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THE IMPACT OF CLIMATE CHANGE ON
SUBTIDAL AND INTERTIDAL BENTHIC
SPECIES IN SCOTLAND
Report to Scottish Natural Heritage from the
Marine Biological Association of the UK
Keith Hiscock
Alan Southward
Ian Tittley
Adam Jory
&
Stephen Hawkins
January 2001
THE IMPACT OF CLIMATE CHANGE ON SUBTIDAL AND INTERTIDAL BENTHIC
SPECIES IN SCOTLAND
Contents
Contents .................................................................................................................................. i
List of Figures and Tables ................................................................................................... iii
ABSTRACT ............................................................................................................................. v
1.
INTRODUCTION........................................................................................................... 1
1.1 Species and biotopes in Scotland ........................................................................ 1
2.
3.
1.2
Current climate – seawater temperatures ....................................................... 1
1.3
Past climates ...................................................................................................... 1
1.5
Establishing recent effects of climate change in north-east Atlantic waters
– finding baselines............................................................................................. 5
1.6
Evidence for effects of change in species due to seawater warming
elsewhere ......................................................................................................... 10
SPECIES AND BIOTOPES TO BE RESEARCHED .................................................. 10
2.1
Species and biotopes included in statutes, directives and Biodiversity
Action Plans ..................................................................................................... 10
2.2
Species and biotopes with a restricted distribution in Scotland ................ 10
2.3
Selecting species and biotopes to be included in assessment .................. 13
LITERATURE REVIEW - CURRENT DISTRIBUTIONS ............................................ 14
3.1
4.
The sources and nature of distributional records ........................................ 14
KEY ENVIRONMENTAL FACTORS THAT DEFINE DISTRIBUTIONAL RANGE .... 14
4.1
Presence of suitable habitats ......................................................................... 14
4.2
Temperature ..................................................................................................... 14
4.3
Hydrographical conditions - direction of currents ....................................... 15
4.4
Geographic barriers......................................................................................... 16
4.5
Water ‘quality’ .................................................................................................. 16
5.
LIKELY EFFECTS OF CLIMATE CHANGE ON MARINE ECOSYSTEMS ............... 16
6.
MECHANISMS OF CLIMATE CHANGE EFFECTS................................................... 17
7.
LIKELY EFFECTS OF CLIMATE CHANGE ON SPECIES ....................................... 18
7.1
Introduction ...................................................................................................... 18
7.2
Effects of increase in air temperatures on open shore species.................. 19
7.3
Effects of increased air temperatures on species in enclosed waters....... 19
i
8.
9.
7.4
Effects of increased air temperatures on surface waters and intertidal
isolated water bodies (rockpools).................................................................. 19
7.5
Effects of increase in seawater temperatures............................................... 20
7.6
Biotic interactions............................................................................................ 20
DEVELOPING A ‘RULE BASED’ SYSTEM FOR ASSESSING LIKELY EFFECTS
FOR A PARTICULAR SPECIES ................................................................................ 21
8.1
Components ..................................................................................................... 21
8.2
Mechanisms - effects for southern species in a temperature rise scenario22
8.3
Mechanisms - effects for northern species in a temperature rise scenario22
8.4
Mechanisms – the importance of residual currents. .................................... 23
8.5
Exceptions - localised effects in isolated waters ......................................... 23
8.6
The ‘key’ - determining the likely effects of temperature increase on a
particular species ............................................................................................ 23
EXAMPLES OF POSSIBLE CHANGE....................................................................... 26
9.1
Likely effects on representative species ....................................................... 26
9.2
Likely effects on susceptible biotopes .......................................................... 27
10.
LOCATIONS WHERE CHANGE MIGHT BE PARTICULARLY ACUTE ................... 27
11.
RELEVANCE TO SCOTTISH SACs .......................................................................... 28
12.
RECOMMENDATIONS FOR FUTURE ACTION BY SNH ......................................... 29
13.
REFERENCES AND BIBLIOGRAPHY OF RELEVANT LITERATURE .................... 32
APPENDICES........................................................................................................................ 41
Appendix 1. Information on species distributions from A.J. Southward and S.J.
Hawkins ............................................................................................................ 41
Appendix 2. Benthic marine species which occur in Scotland or may spread
there or be affected by expected climate change and which are listed in
statutes, directives or Biodiversity Action Plans. ........................................ 45
Appendix 3. Benthic biotopes which are part of Biodiversity Action Plans
(BAPs) and are either found in Scotland or are likely to spread there in
response to expected climate change. .......................................................... 47
Appendix 4. Species with climatically restricted distributions or abundance in or
near Scotland ................................................................................................... 51
Appendix 5. Basic information for species with a limited geographical range in
or near Scotland whose distribution might change due to global warming.61
Appendix 6. Detailed information sheets for biotopes that are part of
Biodiversity Action Plans or that may change in distribution as a result of
climate change. .............................................................................................. 127
Appendix 7. Predictions of climate change (temperature rise) for selected
representative species. ................................................................................. 155
ii
List of Figures and Tables
Figure 1: Recent mean seawater temperatures around Britain for summer (top) and winter
(bottom). (From Hiscock, 1998, re-drawn from Lee & Ramster, 1981.).......................... 2
Figure 2: Long-term change. Oceanographic and palaeoceanographic maps of the
northeast Atlantic depicting inferred surface currents and ecologic water masses. (After
Ruddiman & McIntyre, 1976.). ......................................................................................... 3
Figure 3: Global surface temperatures (combined land, air & sea temperatures) from 1840
to 1999. (From: http://www.meto.govt.uk/sec5/CR_div/GlobeTemp.) © Crown
Copyright…………………………………………………………………………………………4
Figure 4: Global temperature rise due to increase in greenhouse gases. Predicted changes
in (from upper to lower lines) land, global, sea and ‘unperturbed’. (From:
http://www.meto.govt.uk/sec5/CR_div/Brochure98/index.html.) © Crown Copyright……4
Figure 5: Biogeographical characteristics of the coast of the British Isles including the range
limits of some species. From Forbes (1858)………………………………………………..6
Figure 6: The direction of near-surface residual currents around the British Isles. (From
Hiscock, 1998, re-drawn from Lee & Ramster, 1981)……………………………………..15
Figure 7: Water currents and quality decision tree for southern species…………………….26
Figure 8: Location of proposed and candidate SACs in Scotland (map supplied by SNH,
square brackets added to indicate sites without seabed habitats)………………………28
Table 1: Northern and southern species with good distributional records that are considered
to have climatically restricted distributions in or near Scotland………………………….11
Table 2. Biotopes with good distributional records that are considered to have climatically
restricted distributions in or near Scotland and that might be affected by climate change.
* = Biotopes for which more detailed information is given in Appendix 6………………12
Table 3. Initial proposed list of locations around the Scottish coast that could be targeted for
establishing a baseline and recording change in species abundance and presence in
relation to climate change. Sites that are known to be in proposed or candidate SACs
are emboldened………………………………………………………………………………30
iii
iv
THE IMPACT OF CLIMATE CHANGE ON SUBTIDAL AND INTERTIDAL BENTHIC
SPECIES IN SCOTLAND
ABSTRACT
Keywords: Climate change; seabed wildlife; species distribution.
1. SNH require to know what impact climate change might currently be having and what
effect it might have in the future on seabed wildlife around the coast of Scotland.
2. The marine flora and fauna of Scottish waters, excluding bacteria, non-lichenous fungi,
viruses and Protista includes in the order of 8,500 species. About 230 of the 263 seabed
biotopes catalogued from around the British Isles are recorded from Scottish waters.
3. Occurrence and distribution of species in Scotland is ultimately determined by seawater
temperatures with many species reaching their northern or southern geographical limits in
Scotland. Other factors that are important in determining species distributions include the
direction of prevailing currents northwards along the west coast and offshore islands and the
‘quality’ of water on the west coast which seems to favour survival of some species usually
associated with the south-west of the British Isles. Biogeographical differences around
Scotland are increased by the greater cooling of water during winter in the North Sea.
4. The most recent predictions suggest that, by 2100, average air temperatures may be
between 2 and 4°C higher than at present and seawater temperatures may be as much as
2°C higher than in 2000. The rise of inshore seawater temperature may be higher than the
oceanic average. In addition to increased air and seawater temperatures, increased
storminess and alterations in major current patterns may occur as a result of climate change.
5. Important factors to take into account when identifying likely changes in distribution as a
result of warming are the reproductive biology of species, the presence of physical or
hydrographic barriers to the spread of species, the importance of water quality, and the
possible over-riding importance of local conditions to survival of species. At present, despite
evidence of warming in both air and sea temperatures in Scotland in recent years, we cannot
point unequivocally to changes in abundance or distribution of seabed species that can be
ascribed to climate change around the Scottish coast.
6. The rate of geographical extension or reduction of distributional extent or change in the
abundance of species at existing locations in response to increases in temperature are likely
to be determined by a range of factors that are represented in a ‘key’ and decision tree.
7. One hundred and twenty nine species and 30 biotopes are identified as likely to be
representative of the changes which may occur in distribution and abundance of species and
biotopes in seabed habitats around Scotland as a result of any increased air and sea
temperatures over the next 100 years. Distributional and other relevant information is given
for 63 species expanded for 23 of those species to provide examples of likely changes in
distribution and abundance for scenarios of a rise in seawater temperature of one and two
degrees centigrade. Distributional and other relevant information including a description of
likely change is given for 21 biotopes which are included in Biodiversity Action Plans or are
likely to be modified in composition and/or distribution as a result of any increased air and
sea temperatures over the next 100 years.
8. Overall, it is expected that a warming of air and seawater temperatures will result in
increased diversity of seabed marine life in Scotland with adverse effects limited mainly to
declines in abundance or loss of a small number of northern species. Changes to a minority
of biotopes might occur in the long term but they include some that are ‘special’ to Scotland
including maerl and horse mussel beds.
9. Targeted surveys are required now to establish baselines and wider recording schemes
focussed on conspicuous easily identified indicator species should be initiated.
v
vi
THE IMPACT OF CLIMATE CHANGE ON SUBTIDAL AND INTERTIDAL BENTHIC
SPECIES IN SCOTLAND
1. INTRODUCTION
1.1 Species and biotopes in Scotland
Based on the collation of species numbers included in Davison (1996), the marine flora of
Scotland, excluding bacteria, lichens, non-lichenous fungi and viruses, includes about 2,400
species of which about 800 are benthic algae. The marine fauna of Scotland, excluding
Protista, Insecta and Aves includes about 6,090 species of which about 4,500 are benthic
species. The wide range of habitats present in Scotland, encompass about 230 of the 263
separate seabed biotopes currently catalogued around the British Isles (derived from the list
of biotopes in Connor et al., 1997 a&b). Many of those species and biotopes are widely
distributed in the north-east Atlantic, but some species are especially abundant or only found
in Scotland in Great Britain. There are no seabed species believed to be endemic to
Scotland.
1.2 Current climate – seawater temperatures
The seawater temperature range, both bottom and surface temperatures for summer and
winter, for the British Isles are shown in Figure 1. The western coasts are greatly affected by
the warm water of the North-East Atlantic Drift. However, the enclosed nature of both the
North and Irish Seas means that winter temperatures are much colder than on the open
Atlantic coast, although local warming can occur in the summer. Water temperature is of
greatest importance in determining the distribution of species although air temperature and
the amount of direct sunlight are important for littoral communities.
1.3 Past climates
Climate change is a feature of the history of the earth. Studies of seabed deposits reveal
large-scale and long-term changes in species that characterise particular temperature
regimes. Climate change including seawater temperature rise may be rapid (see Figure 2).
‘Rapid’ in climate change terms can mean, for instance, that, at the end of the last glaciation,
it took almost four centuries for sea surface temperature in the north-east Atlantic to rise by
10 °C (Bard et al., 1987). During interglacial periods, climate may still change suddenly
(within less than a century) (see, for instance McManus et al., 1994; Broecker, 1997; Adkins
et al., 1997). Written history is much shorter than the geological record but significant
changes in air and seawater temperatures have been recorded in the past thousand years or
so based on various texts and observations. For instance, Lamb (1977) uses various
sources of information including direct temperature readings and fisheries records to
conclude that, in about the past 150 years, seawater temperature in the north Atlantic might
have risen by about 0.5 to 1.0 °C. Rises in temperatures can be quite rapid; for instance, off
southern Iceland the rise between 1910-1919 and 1940-1949 was 2.1°C. Sometimes those
changes take place over only a few years or decades but last for centuries. Much further
back (between about 800 and 1300 AD), it seems that there was a period when seawater
temperatures in the north Atlantic were warmer than today. Some evidence, such as the
occurrence of cod off Greenland (cod require water temperatures above 2°C), does suggest
higher temperatures than in recent times but other evidence is more circumstantial. The
following, which relates to a Viking settlement in southwest Greenland in the years between
985 and 1000 AD, is copied from Lamb (1988):
“Of one of the leading original settlers, a cousin of Erik the Red, named Thorkel Farserk,
who settled at Hvalseyjarfjord, it is related that: ‘He was extremely strong. Erik the Red once
visited him. As he wished to entertain his cousin well, but had no serviceable boat at hand,
he had to swim out to Hvalsey to fetch a full-grown sheep, and carry it home … it was a
distance of well over 2 miles’ …. 10°C would be a fair estimate of the lowest temperature at
which a person not specifically trained in long-distance swimming could swim 2 miles, and
even then he would have to be fat. …. As the average temperature in the fjords of that
1
Figure 1: Recent mean seawater temperatures around Britain for summer (top) and winter
(bottom). (From Hiscock, 1998, re-drawn from Lee & Ramster, 1981.).
2
Figure 2: Long-term change. Oceanographic and palaeoceanographic maps of the
northeast Atlantic depicting inferred surface currents and ecologic water masses. (After
Ruddiman & McIntyre, 1976.).
Maximum interglaciation, 120,000 years BP
Maximum glaciation, 18,000 years BP
60
50
40
30
Deglaciation, 9,300 years BP
Present
60
50
40
30
30
Polar
20
10
30
Subpolar
Transitional
3
20
10
Subtropical
coast in August in the warm years around 1950 were +3°C to +6°C, it seems that
the water must have been at least 4°C warmer in the years concerned in Viking
times.”
Clearly such stories may exaggerate the physical prowess of the Vikings but it is a useful
indicator of different conditions.
1.4 Recent changes in climate
Figure 3: Global surface temperatures (combined land, air & sea temperatures) from 1840 to
1999. (From: http://www.meto.govt.uk/sec5/CR_div/GlobeTemp.) © Crown Copyright.
1.0
Change in temperature (degrees C)
0.8
0.6
0.4
0.2
0.0
-0.2
-0.4
1850
1900
1950
2000
Year
Figure 4: Global temperature rise due to increase in greenhouse gases. Predicted changes
in (from upper to lower lines) land, global, sea and ‘unperturbed’. (From:
http://www.meto.govt.uk/sec5/CR_div/Brochure98/index.html.) © Crown Copyright.
7
Temperature difference (degrees C)
6
Land
5
Global
4
Sea
3
2
1
Control
0
-1
1860
1900
1940
1980
2020
Year
4
2060
2100
Evidence is now increasing that human activities are influencing climate change and that
change includes significant warming of the atmosphere with inevitable consequences on
seawater temperature.
The most recent predictions and historical precedents suggest that it is most likely that
Scottish inshore waters will be subject to a progressive increase in seawater temperatures
over the next few years. By 2100, average air temperatures may be between 2 and 4°C
higher than at present; sea level may have risen by 50 cm (www.doc.mmu.ac.uk/aric/
ace/online_info/gcc) and seawater temperatures may be as much as 2°C higher than in
2000 (www.meto.govt.uk/sec5/CR_div/Brochure98/index.html; Wood et al.1999) However,
coastal water temperatures in Scotland have already risen by about 1°C between 1970 and
1998 (Turrell, 1999) and it may be that, in enclosed waters especially, the rise of inshore
seawater temperature may be higher than the oceanic average.
All of the evidence currently available suggests that seawater temperatures in inshore
waters will:
•
continue to show significant short term variations with the possibility of maximum and
minimum sea surface temperatures in any one year being 2 °C above or below the
average at the time, but
•
there will be a trend towards higher average temperatures which, even in the most rapid
change scenarios, would be unlikely to result in a long-term increase in average
temperature of sea surface temperatures of more than 2 °C over the next 50 years, and
•
enclosed waters with restricted exchange to the open sea may warm to a greater extent
than average conditions in the open sea and especially if summer air temperatures are
significantly warmer than at present.
Predictions of likely seawater temperature rise are much more sparse than for air
temperatures but the work of Wood et al. (1999) seems to indicate that an increase in
temperature of about 3°C between 1858-69 to 2089-99 around Scotland may occur.
However, since the temperature of Scottish inshore waters has risen by about 1°C between
1970 and 1998 (Turrell, 1999), temperature rise in those inshore waters might be higher than
for the north-east Atlantic generally.
Any true long-term change is likely to be obscured initially by short-term changes driven (for
instance) by the decadal but irregular cycle of the North Atlantic Oscillation (Hurrell, 1995),
the 11-year cycle of sunspot activity (Southward et al., 1975), or by longer-term fluctuations
such as the Russell cycle (Russell, 1973; Flushing & Dickson, 1976; Southward, 1980).
Uncertainties abound – not least the possibility that melting polar ice may resulting in
‘switching-off’ or at least slowing of the ‘Atlantic conveyor belt’ which draws warm water
northwards along the western seaboard of Europe. Even if changes in seawater
temperatures lag behind those on land or are modified by changes in current patterns,
intertidal organisms will be influenced by air temperatures and sunlight regimes during
emersion.
1.5 Establishing recent effects of climate change in north-east Atlantic waters –
finding baselines
The distribution of marine species has been studied for a long time in Britain, although the
term ‘biogeography’ has been in regular use only for the past 60 years. The distribution of
marine life was put on a scientific basis by Edward Forbes, during the first half of the 19th
century. Forbes was of Scottish descent, brought up in the Isle of Man, and was a
competent field worker and taxonomist who also became an expert in geology and
palaeontology as head of the Geological Survey. He was appointed to the Chair of Natural
5
Figure 5: Biogeographical characteristics of the coast of the British Isles including the range
limits of some species. From Forbes (1858).
The “Line of coast upon which western littoral types occur” extends along the outer west
coast and the north coast of Scotland and includes all of Orkney. Current nomenclature is:
Acmaea testudinalis = Tectura testudinalis (a limpet); Cytherea chione = Callista chione (a
bivalve); Echinus lividus = Paracentrotius lividus (purple sea urchin); Fusus norvegicus =
Volutopsis norwegicus (a snail); Haliotis = Haliotis tuberculata (the ormer); Rhynconella
psittacea = Hemithiris psittacea (a snail); Trichotropis borealis (a snail); Echinus neglectus =
Strongylocentrotus droebachiensis (a sea urchin).
History in Edinburgh in 1854, but died the same year. His ideas of distribution, including
fossils, are given in the first report of the Geological Survey (Forbes, 1848), but his detailed
maps of marine life were published posthumously (Forbes, 1858; Forbes and GodwinAusten, 1859). Figure 5, reproduced from Forbes (1858) is an inset into a larger map of the
world, showing the distribution of key species around the British Isles. Forbes recognized an
east/west divide in the British Isles. The fauna of the west coasts of Britain, from the Isle of
Wight around to the Orkney Islands, includes what Forbes calls “western elements”, mostly
species of warm water or southern character. In contrast, the eastern coasts of Britain have
a more northern character. The British Isles coincide with a boundary between cold-water,
northern forms and warmer water, southern species. However, the situation was, and still is,
complicated by the occurrence of what Forbes called “outliers”. For example “boreal
outliers” are cold water species that he showed as present in deeper waters of the western
Scottish sea lochs, off Galway and in the western Celtic Sea. Warmer water or “Lusitanian
outliers” were shown in the western English Channel. Forbes drew a line across the British
Isles, roughly from Beachy Head to Donegal, noted as the general northern and eastern limit
of southern types. He also depicted the limited distribution of the warm-water sea urchin
Paracentrotus (as Echinus) lividus, apparently restricted then to the coast of Ireland from
6
south-west Cork to Donegal Bay. We may note that there were no Scottish records of this
sea urchin at the time.
The interpretation provided by Forbes is of special importance when considering the effect of
climate change on shallow water and intertidal life of Scottish waters. There is the contrast
between the eastern and western coasts, and while the outer islands and western coasts
include southern species, the deeper western lochs also hold species typical of colder, more
northern waters. These boreal outliers might be regarded as relicts of the period when the
last ice age was abating and the climate warming. The question is whether these northern
species can maintain themselves if further warming occurs, as discussed in later sections of
this report.
After the establishment of marine laboratories around Britain in the 1880s, the staff and
visitors to these places collaborated in drawing up comprehensive lists of the fauna and
flora, as for example at Plymouth, Port Erin, Millport and Cullercoats. Some lists did not get
beyond local archives but others have been published as books (Marine Biological
Association, 1957; Bruce et al., 1963; Foster-Smith, 2000) and others appeared as
occasional publications at various levels of higher taxa (e.g. Wilkie, 1989). These works
provide us with valuable detailed baseline data for restricted localities that can then be used
to check and improve some of the wider ranging biogeographical surveys.
Further studies of distribution of marine life along British coasts were made in the 1920s,
1930s and 1950s (Fischer-Piette, 1936; Russell, 1935; Moore & Kitching 1938; Crisp &
Southward 1958, summarised in Lewis, 1964). Most of these authors were concerned to
identify the environmental factors controlling the distributions, including climate and water
movements. Field ecological studies of this type became less popular after the 1960s, when
it was easier to obtain support for laboratory studies of processes and systems. There was
a short revival of interest in distribution in the late 1960s, following disastrous oil-spills, when
it became urgent to establish baseline information on British shores (Powell et al., 1979,
1980a, 1980b; Crisp et al. 1981). Afterwards, laboratory studies again became ascendent.
In the last decade, interest in distribution has been re-kindled to help conserve biodiversity
(various reports from the Marine Nature Conservation Review of Great Britain listed in
www.jncc.gov.uk/corporate) and to follow the likely consequences of climate change
(Southward & Boalch, 1994). A parallel line of investigation of coastal marine life has been
the study of its zonation and the factors that structure the community, including biotic
interactions as well as abiotic factors. As examples we can cite Lewis (1964) and his later
collaborators (references in Moore & Seed, 1985) who studied, among other things,
recruitment and who added to our knowledge of geographical distribution. Then there is the
school at Port Erin, principally concerned with biotic interactions (references in Rafaelli &
Hawkins, 1996), but who were also interested in distribution.
Lewis and co-workers (Lewis, 1964; Lewis et al., 1982; Bowman & Lewis, 1986; Kendall &
Lewis, 1986; Lewis, 1986; Kendall, 1987; Kendall et al., 1987; Lewis, 1996, 1999) have
undertaken various studies of species which reach or are near their northern limits in
Scotland, particularly Gibbula umbilicalis, Chthamalus spp. and Patella ulyssiponensis (P.
aspera). They provided clear evidence that both the extreme limits and population structure
and abundance towards these limits are set by recruitment processes including reproductive
output, larval survival and early juvenile survival post-settlement. More recently Lewis
(1996, 1999) has eloquently argued the case for use of the study of reproduction and
recruitment as a means of monitoring climate change. The detailed published work
spanning the 1970s and 1980s will provide an excellent baseline to judge changes with
global warming, especially for G. umbilicalis. We anticipate these populations will expand as
recruitment becomes more regular. There are also many unpublished data for this group
that are of value and need to be accessed and archived (M. Kendall, pers. comm.).
Although only a small amount of survey work was published, fortunately there are
considerable archives of the results of investigations of Scottish rocky shores from 1953 to
7
1962. The period from 1962 to 1980 saw a decline in sea temperatures, coinciding with
increases in cold water species of plankton and fish in the English Channel (Southward et al.
1995). Hence care is needed in interpreting unpublished data on distribution of intertidal and
shallow water benthos during this period.
The symposium volume on the Islands of Scotland (Baxter & Usher, 1994), gives a general
picture of Scottish inshore marine life and the need for conservation. In that volume Sole
Cava et al. (1994) take note of the isolating effect of islands upon the genetic make up of
marine animals with reduced dispersal, and this must add to the complexity of distribution of
marine life in Scottish west coast waters. Animals with a planktonic larval stage may still
have difficulties in spreading across sea barriers, even such a short distance as from South
Wales to Ireland, a barrier not yet crossed by two southern species - the barnacle Balanus
perforatus and the limpet Patella depressa (Crisp & Southward 1953). Furthermore, the Irish
Sea differs environmentally from the more wave-beaten western coasts of Ireland and
Scotland, and a species spreading northwards from south-west England might have to
colonise Ireland first (e.g. Chthamalus stellatus is absent from Northern Irish Sea Basin,
Crisp et al., 1981).
Recent observations have been made of changes that might be the result of climatic change.
The southern topshell G. umbilicalis has increased in abundance greatly within Strangford
Lough in Northern Ireland in recent years whilst the northern tortoiseshell limpet Tectura
testudinalis cannot now be found at the entrance to the lough or on the open coast of the
Ards Peninsula in Northern Ireland (J. Nunn, pers. comm.). Similarly, T. tessulata has not
been readily seen in recent years on the south coast of the Isle of Man (S.J. Hawkins, own
observations), where it was previously quite common.
An important feature of the Scottish coast is the contrast between the wave-beaten outer
shores and offshore islands and the sheltered habitat of the lochs. As in other regions with
long fjords, notably Norway, British Columbia and Alaska, the outer shores are dominated by
southern elements, together with a few Arctic or Boreal forms that favour strong wavebeaten habitats. For example, the warm water barnacle, C. stellatus, is the only chthamaloid
on North Rona; it is a species of wave-beaten headlands on the mainland coast where it
may outnumber Chthamalus montagui, a species better adapted to embayed conditions. In
contrast, the boreo-arctic barnacle, Semibalanus balanoides flourishes inside the long
mainland sea lochs and is similarly distributed inside the Alaskan fjords. Many of these cold
water species appear to be better adapted than the southern types to endure the seasonally
varying lower salinities that they may experience inside the lochs/fjords. However, the
western coasts of Orkney, the outer Hebrides and Ireland from Donegal to Kerry carry
populations of Fucus distichus anceps, a boreal alga that prefers extreme wave action.
There are other exceptions; some enclosed sea lochs such as Loch Sween, become
stratified, like Norwegian ‘pollens’ and the intertidal zone may show the southern species, C.
montagui outnumbering the cold water species S. balanoides, in the upper midlittoral.
Catches or sightings of species of fish normally found south of the area where they are
reported are frequently considered to be harbingers of climate change. Invertebrate species
and algae are much less reported although, for instance, catches of the mantis shrimp,
Squilla desmaresti in the English Channel in 1999 and its discovery in Cardigan Bay (R.
Holt, pers. comm.) caused some excitement (although records of the species in the Channel
extend back to 1900). In Scotland, the identification of the southern species of feather star
prawn Hippolyte prideauxiana at Loch Carron (S. Scott, pers. comm.) may be a chance
observation of a long-term presence or may reflect some effect of climate change
encouraging larval survival and settlement.
Attempts at a synthesis of distribution of shallow water life have been mostly regionally
based (e.g. Fischer Piette, 1936; Crisp & Southward, 1958; for the English Channel coasts:
Southward & Crisp, 1954 for Ireland) or else restricted to one or few species (e.g. Moore &
Kitching, 1939 for Chthamalus; Powell, 1957 for Fucus distichus). These last two
8
contributions do deal with Scotland, but have gaps in coverage while treating particular
regions in detail. To improve the situation for Scotland, D.J. Crisp and A.J. Southward
carried out low budget field surveys of rocky shores from 1953 to 1962, with the help of small
grants from the Royal Society. Data from these surveys were supplied to other authors, for
example to J.R. Lewis, who published maps of distribution of certain species around the
British Isles in his book on rocky shores and made a national synthesis (Lewis, 1964). Other
publications taking data from the surveys were Crisp et al. (1981) and Southward et al.
(1995). Unfortunately, compilers of other works on distribution have not been able to make
use of these unpublished data, and some authors seem to have passed over the local fauna
lists as well, giving erroneous pictures of certain species.
Since there was a cool period in Britain between 1962 and 1980, we should restrict
ourselves to the records before 1963 as a baseline and then carry out fresh surveys in the
future to determine if distributions have changed. Data from the cool period can be expected
to show declines in warm water species and increases in boreal species, such as detected in
the plankton and fish in the English Channel (Southward, 1980; Southward et al. 1995).
There is a problem that there was only a small amount of quantitative estimation in the cool
period. For example, many of the biodiversity surveys were and are qualitative or semiquantitative in their approach.
The Crisp and Southward archives for Scottish localities do contain repeat counts of certain
species after 1962, but these are for a few places only and need careful assessment and
comparison with the data for south-west England. Annual surveys of certain species were
made at up to 40 localities around south-west England from 1955 to 1987, and a few
stations have been continued to date. These show definite changes in the intertidal fauna
during the cool period, comparable to those seen in plankton and fish. The Crisp and
Southward data for Scotland offer some comparisons between 1953/62 and the
1970s/1980s, but there are too few records in the later period to offer statistical proof of
change. To detect future changes in Scottish waters we need to set up a network of
reasonably accessible stations, enough in number to provide sound statistics, where
selected species can be enumerated each year. Much could be done photographically if
advantage was taken of new digital technology, providing not only non-intrusive sampling but
also a permanent record.
Some specific examples of changes or likely changes in distribution are described in greater
detail in Appendix 1.
All-in-all, there are few comprehensive baselines from which to assess change in distribution
and abundance of seabed marine species in recent times, and obtaining validated records is
a problem. The results of the extensive Marine Nature Conservation Review surveys
available on MERMAID (Marine Environmental Resource Monitoring And Information
Database) (www.jncc.gov.uk/mermaid/) give a good indication of the distribution of many
conspicuous mainly epibenthic species, but some records that are illustrated require
checking and validation.
There are authentic early (sixteenth century) accounts of the marine flora of the North Sea
from Thanet, Kent in the herballs of Gerard (1597) and Johnson & Gerard (1633). These
allow a glimpse of the marine flora at that time, and cite Fucus serratus, Fucus vesiculosus,
Halidrys siliquosa, Laminaria digitata, Laminaria saccharina, Corallina officinalis, Palmaria
palmata and Ulva lactuca, species which form the principal vegetational features on the
chalk foreshore today. Their continued presence suggests stability in inshore water
temperatures over the past 400 years; however, the warm-water brown alga Padina
pavonica was recorded from Thanet in the nineteenth century. P. pavonica reaches its
northern distributional limit in southwestern England but occasionally occurs to the north and
east (Price et al., 1979). Its sporadic occurrence on Thanet may be because it is at the limit
of its environmental tolerance and therefore susceptible to small fluctuations in
9
environmental conditions. The spread of P. pavonica beyond its generally accepted
boundaries could also be an indication of raised temperatures (climate change).
Although such long-term information is not available for the marine flora of Scotland, there
are reliable, comprehensive accounts for the nineteenth century which provide a baseline for
comparison. These indicate, for example in the Edinburgh area of the Firth of Forth,
changes (loss) in the main vegetational features (biotopes) and algal diversity generally;
literature accounts and museum records reveal a formerly much richer and luxuriant marine
flora compared with that of today (Wilkinson & Tittley, 1979; Wilkinson et al., 1988). These
changes probably relate to a deterioration in water quality (due to discharge of polluting
substances and consequent increased load of particulate matter) than to inshore water
temperatures. Another example is for the Orkney Islands; two areas in particular (Skaill Bay
and Kirkwall) have a good recorded history with extensive records from Traill in the 1880s
and herbarium specimens at the Natural History Museum from the 1830s. The results of
field surveys were also undertaken in1973 and recently in 1998/9 suggest little change at
Kirkwall in the last 26 years but show that many species may have been lost since the 19th
century (Wilkinson et al., 2000). This could be ascribed to large scale coastal reclamation at
Kirkwall about 100 years ago. At Skaill Bay, in contrast, species loss has not occurred
suggesting stability in marine algal assemblages over the past two centuries despite
increased inshore sea temperatures (see above).
1.6
Evidence for effects of change in species due to seawater warming elsewhere
Responses of benthic species to increases (or decreases) in seawater temperatures over
long periods are sparse. Barry et al. (1995) report significant increases in the density of
southern intertidal species and decreases in abundance of northern species at Monterey,
California during the period from 1932 to 1993. During that period, mean summer maximum
air temperatures increased by about 2.2 °C and shoreline seawater temperatures by about
0.75 °C (Sagarin et al., 1999).
There is far more evidence for fisheries with switches in species being recorded for sardine
and anchovy which may be linked to temperature either directly or indirectly due to changes
in oceanographic regime including upwelling (Cushing, 1975). Fluctuations in recruitment
and hence abundance of a variety of stocks have also been linked to climate (Cushing,
1975). Cushing & Dickson (1976) have summarized climate-related biological trends in
north-east Atlantic waters up to 1975. Planktonic changes have also been recorded following
the analysis of long term data from continuous plankton recorders (Aebischer et al., 1990).
2.
SPECIES AND BIOTOPES TO BE RESEARCHED
2.1
Species and biotopes included in statutes, directives and Biodiversity Action
Plans
All of the inshore seabed species and biotopes that occur in or near Scottish waters and that
are specifically identified for protection under legislation including directives or for which
Biodiversity Action Plans have been prepared are included in Appendix 2 and 3. However,
the ‘habitats’ included in the Habitats Directive can encompass most rock and many
sediment biotopes present in Scotland and are not therefore included in the review.
2.2
Species and biotopes with a restricted distribution in Scotland
Appendix 4 gives the ‘long-list’ of species with good distributional records that were first
considered (and which others might consider) to have climatically restricted distributions in
or near Scotland. The Appendix also includes reasons, where relevant, for exclusion from
the final short-list of representative or important species for detailed research. Table 1
shows those species which have northern or southern centres of distribution. The northern
species are expected to decrease in abundance, have a more restricted range or even
become extinct in some cases in Scotland. The southern species have been divided into:
10
1. those that at present are not found in Scotland, but are expected to spread there due to
climate change, and
2. those species that are already recorded in Scotland and are expected to extend their
range or increase in abundance due to global warming.
Table 1: Northern and southern species with good distributional records that are considered
to have climatically restricted distributions in or near Scotland.
* = Species recommended for establishment of current distribution and abundance and to be
considered in schemes for monitoring change. Further information on each species is given
in Appendix 4. (Names follow Howson & Picton, 1997 except for Pentapora fascialis
(Pallas)).
Southern species not
currently recorded in
Scotland but which
may spread to
Scotland
Ciocalypta penicillus *
Haliclona angulata
Gymnangium montagui
Eunicella verrucosa *
Aiptasia mutabilis
Balanus perforatus *
Maja squinado *
Osilinus lineatus *
Patella depressa *
Crepidula fornicata
Tritonia nilsodheri
Solen marginatus
Phallusia mammillata
Scinaia furcellata
Chondracanthus acicularis
Stenogramme interrupta *
Laminaria ochroleuca
Bifurcaria bifurcata *
Cystoseira baccata *
Cystoseira foeniculaceus
Southern species currently recorded in Scotland
whose extent of distribution or abundance might
increase
Axinella dissimilis *
Hemimycale columella
Phorbas fictitius
Haliclona cinerea
Haliclona fistulosa
Haliclona simulans
Alcyonium glomeratum *
Anemonia viridis *
Aulactinia verrucosa
Corynactis viridis
Sabellaria alveolata
Chthamalus montagui *
Chthamalus stellatus *
Hippolyte huntii
Palinurus elephas *
Polybius henslowi
Ebalia tumefacta
Corystes cassivelaunus
Liocarcinus arcuatus
Liocarcinus corrugatus
Goneplax rhomboides
Pilumnus hirtellus
Xantho incisus
Xantho pilipes
Tricolia pullus
Gibbula umbilicalis *
Patella ulyssiponensis *
Bittium reticulatum
Cerithiopsis tubercularis
Melaraphe neritoides
Calyptraea chinensis
Clathrus clathrus
Ocenebra erinacea
Acteon tornatilis
Pleurobranchus membranaceus
Atrina fragilis
Crassostrea virginica
Cerastoderma glaucum
Gari depressa
Pentapora fascialis *
Asterina gibbosa
Paracentrotus lividus *
Holothuria forskali *
Centrolabrus exoletus
Crenilabrus melops
Ctenolabrus rupestris *
Labrus mixtus *
Thorogobius ephippiatus
Scinaia trigona
Asparagopsis armata
Bonnemaisonia hamifera
Naccaria wiggii
Jania rubens
Lithothamnion corallioides
Mesophyllum lichenoides
Calliblepharis ciliata
Kallymenia reniformis
Rhodymenia delicatula
Rhodymenia holmesii
Rhodymenia pseudopalmata
Halurus equisetifolius
Sphondylothamnion multifidum
Drachiella heterocarpa
Drachiella spectabilis
Stilophora tenella
Halopteris filicina
Dictyopteris membranacea*
Taonia atomaria *
Carpomitra costata *
Cystoseira tamariscifolia
Codium adhaerens*
Codium tomentosum
Northern species which
may either decrease in
abundance and extent
or disappear from
Scotland
Thuiaria thuja *
Swiftia pallida *
Bolocera tuediae
Phellia gausapata *
Lithodes maia
Tonicella marmorea
Margarites helicinus
Tectura testudinalis *
Onoba aculeus
Colus islandicus
Akera bullata
Limaria hians
Anomia ephippium
Thyasira gouldii
Leptometra celtica
Leptasterias muelleri
Semibalanus balanoides *
Lithodes maia *
Strongylocentotus
droebachiensis *
Cucumaria frondosa *
Styela gelatinosa *
Lumpenus lumpretaeformis
Zoarces viviparus
Lithothamnion glaciale *
Phymatolithon calcareum
Callophyllis cristata
Odonthalia dentata *
Sphacelaria arctica
Sphacelaria mirabilis
Sphacelaria plumosa
Chorda tomentosa
Ascophyllum nodosum mackii
Fucus distichus distichus *
Fucus evanescens
Table 2 gives the ‘long-list’ of biotopes with good distributional records that were first
considered (and which others might consider) to have climatically restricted distributions in
or near Scotland. Appendix 5 provides more detailed information and includes reasons,
where relevant, for exclusion from the short-list of representative or important biotopes for
detailed research.
11
Table 2. Biotopes with good distributional records that are considered to have climatically
restricted distributions in or near Scotland and that might be affected by climate change. * =
Biotopes for which more detailed information is given in Appendix 6.
Biotopes found only or predominantly in
Scotland in Great Britain
Code
Biotopes found predominantly south of
Scotland in Great Britain
Name
Code
ELR.FR.Fdis*
Fucus distichus and Fucus
spiralis f. nana on
extremely exposed upper
shore rock.
ELR.MB.Bpat
.Cht*
Chthamalus spp. on
exposed upper eulittoral
rock.
SLR.FX.AscX
.mac*
Ascophyllum nodosum
ecad. mackii beds on
extremely sheltered mid
eulittoral mixed substrata.
MLR.Sab
.Salv*
Sabellaria alveolata reefs on
sand-abraded eulittoral rock.
ECR.BS.Hbow
Eud*
Halichondria bowerbanki,
Eudendrium arbusculum
and Eucratea loricata on
reduced salinity tide-swept
circalittoral mixed
substrata.
LR.Rkp.Par
Paracentrotus lividus in
shallow eulittoral rockpools.
ECR.Efa
.CCParCar*
Coralline crusts,
Parasmittina trispinosa,
Caryophyllia smithii,
Haliclona viscosa,
polyclinids and sparse
Corynactis viridis on very
exposed circalittoral rock.
LR.Rkp.FK
.Sar
Sargassum muticum in
eulittoral rockpools.
MCR.Xfa.
ErSSwi*
Erect sponges and Swiftia
pallida on slightly tideswept moderately exposed
circalittoral rock.
LR.Rkp.Cor*
Corallina officinalis and
coralline crusts in shallow
eulittoral rockpools. ¹
ECR.Alc
ECR.AlcC
ECR.Alc.MaS
Alcyonium digitatum
dominated biotopes.
MCR.Xfa.
ErSEun
Erect sponges, Eunicella
verrucosa and Pentapora
foliacea.
ECR.BS
.HbowEud
Halichondria bowerbanki,
Eudendrium arbusculum
and Eucratea loricata on
reduced salinity tide-swept
circalittoral mixed
substrata.
MCR.M.ModT*
SCR.Mod*
CMX.ModMx*
CMX.ModHo
Modiolus dominated
biotopes.
CMX.SspiMx*
Sabellaria spinulosa and
Polydora spp. on stable
circalittoral mixed sediment.
IGS.Mrl.Phy*
Phymatolithon calcareum
maerl beds in infralittoral
clean gravel or coarse
sand
12
Name
IGS.Mrl.Lgla*
Lithothamnion glaciale
maerl beds in tide-swept
variable salinity infralittoral
gravel.
IMX.MrlMx
.Lcor*
Lithothamnion corallioides
maerl beds on infralittoral
muddy gravel.
IGS.FaG
.HalEdw*
Halcampa chrysanthellum
and Edwardsia timida on
sublittoral clean stone
gravel.
IMS.Sgr.Rup*
Ruppia maritima in
reduced salinity infralittoral
muddy sand.
CMS.Ser*
Serpula vermicularis reefs
on very sheltered
circalittoral muddy sand.
CMU.SpMeg
.Fun*
Seapens, including
Funiculina quadrangularis,
and burrowing megafauna
in undisturbed circalittoral
soft mud.
¹ Sub-biotopes especially
Additionally, some biotopes already present in Scotland but neither predominantly northern
or southern may change as a result of climate change (CMU.Beg*: Beggiatoa spp. on anoxic
sublittoral mud).
2.3
Selecting species and biotopes to be included in assessment
Only those species and biotopes likely to change significantly as a result of climate change
around Scotland have been included in library research. Seabed species and biotopes for
library research have been further identified using the following criteria:
1. species (i.e. northern species) that reach the southern limits of their range in Scotland;
2. species (i.e. southern species) that reach the northern limits of their range in Scotland or
in nearby Ireland, England and/or Wales;
3. species and biotopes included in UK Biodiversity Action Plans and that occur in or near
Scotland;
4. species and biotopes listed in directives and conventions;
5. species and biotopes that are particularly abundant or only found in Scottish waters in
the UK;
6. species where a significant proportion of the world population occurs in Scottish waters;
7. biotopes that presently only occur further south than Scotland but that might extend to
Scottish waters as a result of climate change;
8. species that may be representative, through their reproductive biology, abundance and
distribution, of a suite of similar species.
13
3.
LITERATURE REVIEW - CURRENT DISTRIBUTIONS
3.1
The sources and nature of distributional records
Most sources of information about distribution of species (usually identification guides or
monographs about taxonomic groups) are generalised descriptions. Some, for instance,
distributional atlases for molluscs (Seaward, 1982, 1990, 1993) and decapod Crustacea
(Clark, 1986) provide maps within large sea areas which are unhelpful for indicating
geographical extent of distribution. Where texts give specific geographical locations for
species, they have proved invaluable. Unpublished data collected by A.J. Southward and
D.J. Crisp in the late 1950’s and early 1960’s (at the end of the last warm period) have been
collated for the current study and used in mapping distributions of species. Some sitespecific records required for the present study are held in unpublished databases that we
have not accessed. However, many records have been brought together in the Marine
Nature Conservation Review (MNCR) database (MacDonald & Mills, 1996). The results of
MNCR and other surveys included on the MNCR database are now available on the Internet
on MERMAID (Marine Environment Research, Mapping And Information Database)
(www.jncc.gov.uk/mermaid) which has been used in this review. However, some records on
this database require confirmation as errors may have been made in identification or entry
into the database. Valuable sources of information on the distribution of algae which have
been used in this study are the review of algal distributions in Scotland by Maggs (1986) and
the atlas of 100 species from the British Phycological Society recording scheme (Norton,
1985). South and Tittley (1986) identify that, of the 1200 species of benthic algae listed for
the North Atlantic, 423 species are recorded from Scotland excluding Shetland and 274 are
recorded from Shetland. Sixteen of these Shetland species are not recorded from the rest of
Scotland although 13 of them are recorded from England. Therefore there are three species
which have their only British records in Shetland. France is the most species-rich area of the
north Atlantic followed by England, northern Spain and Ireland. Additionally, the results of a
recent exercise to catalogue the herbarium records for Scotland held by the Natural History
Museum have been used. Where appropriate, distribution maps have been reviewed and
adjusted by relevant researchers.
For rocky shores, the detailed descriptions and photographs in Lewis (1964) can be used to
indicate where biotopes occurred in the 1950s and early 1960s (see also Lewis, 1957a,
1957b; Lewis & Powell, 1960). In Orkney the work of Jones and Baxter also provides a
quantitative baseline from the late 1970s onwards (Baxter et al., 1985).
Appendices 6 and 7 include detailed reviews with maps showing the current recorded
distribution of species and biotopes that reach their northern or southern limits in Scotland or
are at the northern recorded limits of their distribution on nearby coasts.
4. KEY ENVIRONMENTAL FACTORS THAT DEFINE DISTRIBUTIONAL RANGE
4.1
Presence of suitable habitats
Species have required habitats (physical, chemical and sometimes biological) and will only
be found where those habitats occur. Many habitats in Scotland, such as rocky shores, are
widely distributed and so are the species that require that habitat unless some other factor
such as temperature restricts their occurrence. Where a habitat is very restricted in
occurrence (for instance the only habitat for the sea anemone Amphianthus dohrnii in
Scotland is the sea fan, Swiftia pallida, which occur at very few locations) the distribution of a
species will reflect occurrence of the habitat and may not be influenced by physical
conditions such as temperature.
4.2
Temperature
The distribution of many species follows summer or winter isotherms (Figure 1). However,
the reason for temperature affecting distribution (and abundance) varies and includes:
14
•
survival of adults (heat or cold stress);
•
development of eggs or other propagules;
•
‘triggering’ release of propagules;
•
survival of larval stages of animals (in cold waters, larvae may not develop fully to
metamorphosis).
•
survival of post-settlement of juveniles
For some species, local warming might be important. Warm summer temperatures in
surface waters of enclosed areas such as lagoons (including obs), sea lochs or even
rockpools may enable the production of propagules and perhaps survival of local populations
in those isolated locations. Also, waters which remain cool because of thermal isolation of
deeper waters may encourage reproduction in relict populations of species that were much
more widespread in former colder times. In the intertidal, air temperatures can be important
with both extremes of cold (e.g. Crisp, 1964; Todd & Lewis, 1984) and heat (e.g. Hawkins &
Hartnoll, 1985) causing kills. Warmer air temperatures would also be expected to speed
development in southern species but could cause stresses in colder species.
4.3
Hydrographical conditions - direction of currents
Figure 6: The direction of near-surface residual currents around the British Isles. (From
Hiscock, 1998, re-drawn from Lee & Ramster, 1981).
The overall direction of currents (the horizontal movement of water masses after the tidal
element has been removed) around and near to Scotland is illustrated in Figure 6. These
15
currents are important in the distribution of water masses and to spreading the
characteristics of those water masses (including temperature) and in distributing the pelagic
larvae and spores of benthic species.
Currents may also bring larvae from distant sources to establish populations of a species
that are not themselves able to reproduce – either because individuals are too distant from
each other for male and female propagules to meet or because water temperatures are too
cold or too hot for propagules to develop. In this case, occurrence of the species may be
sporadic and only on outward coasts that ‘catch’ the currents.
Currents may also sweep the larvae of intertidal species offshore so that they do not spread
further than the headland or other feature that provides the obstruction causing offshore
direction. The direction of currents may be adverse to the spread of a species. Larval
retention in lochs (such as the Clyde) and bays could lead to localised pockets (Barnes &
Barnes, 1977).
4.4
Geographic barriers
The absence of suitable habitats for the settlement of a species over a large area may mean
that larvae do not survive the time required to reach a suitable habitat for settlement. An
extreme example of such geographical isolation occurs in Scotland for shallow water species
between the Hebrides or Ireland and Rockall. It might also be the case that the distance
between mainland Scotland or Orkney to Shetland including Fair Isle is too great for the
survival of the larvae of some benthic animals. Seaweeds seem to be much less
constrained by geographic barriers in their distribution and may exhibit a continuum of
change with no obvious boundaries or breaks providing that suitable habitats are present.
4.5
Water ‘quality’
Some species may require a particular water ‘quality’ in terms of nutrient status for
propagules to survive or thrive and therefore colonise an area. The importance of water
quality has been demonstrated for the English Channel where the numbers of postlarval fish
and the larvae of other species especially decapods is high when water masses off
Plymouth become of the ‘Sagitta elegans type’ (Russell, 1973). The ‘fertility’ of such water
was also demonstrated by Wilson (1951) in experimental studies rearing larvae. Wilson
(1951) concluded “This is the first observation that has been made to show that the
difference in bottom faunas from one region to another may be related to the ability, or
otherwise, of larval stages to develop in the overlying water mass”. It follows that the
occurrence of many of the south-western species present only on the outer west coast of
Scotland may have much more to do with water quality in the area than temperature.
Increase in water temperatures inshore may not therefore result in wider occurrence of
certain species where water quality is important to larval survival.
5.
LIKELY EFFECTS OF CLIMATE CHANGE ON MARINE ECOSYSTEMS
A wide range of changes to marine environmental conditions may occur as a result of
climate change. Those predicted changes include the following:
1. A rise in seawater temperature. This change, together with a rise in air temperature and
sea level, is occurring already and is likely to continue.
2. A rise in sea level brought about by thermal expansion and by melting ice caps.
3. A rise in air temperature (affecting intertidal ecosystems).
4. Increased levels of ultra violet light (also due to decreasing ozone concentrations in the
stratosphere) adversely affecting some shore organisms and larvae in very shallow
water.
16
5. An increase in variation and extremes including increased ‘storminess’ and greater
winter rainfall and summer drought.
6. In the longer term, a slowing of the North Atlantic ocean circulation decreasing the
amount of heat transported into north-west Europe with a possibility that it might ‘shut-off’
altogether.
However, likely effects may be moderated or exacerbated by other events, For instance,
increased levels of ultra violet light might be moderated if an increase in cloudiness, as
predicted by up to 4% by 2080 (Hulme & Jenkins 1998), occurs.
Although many changes might occur, increased seawater temperature is by far the dominant
factor effecting alterations in distribution and abundance of species and the factor most likely
to occur in the next 50 to 100 years. The next section is therefore dominated by the likely
effect of increased seawater temperature.
6.
MECHANISMS OF CLIMATE CHANGE EFFECTS
Increased seawater temperatures, especially at the time of breeding and larval dispersal are
likely to be effective in increasing the distribution and abundance of southern species in
Scotland through the following mechanisms:
1. More frequent successful gonad development or more broods will lead to greater
reproductive output.
2. Larval development will be accelerated and species that do not currently reach final
stages for settlement because water temperature is too low, will settle.
3. Larval survival will be higher.
4. More consistent recruitment among year classes will occur leading to more balanced age
distribution.
The importance of temperature and likely favourable effects of increased temperature have
been particularly demonstrated in prosobranch molluscs, decapod crustaceans and
barnacles. Many species require temperature to reach a certain high level before spawning
can occur. Such temperature requirements are clearly important in determining whether or
not larvae are produced. Other factors may be important in determining whether larvae
survive and settle. For instance, Lindley (1998) demonstrated that the intermoult times of
the pelagic larvae of decapods was much shorter in warmer waters. Such a shortening of the
developmental time of larvae provides the scope for progression through the different larval
stages within the time limits of the primary productive season and therefore improved
likelihood of survival to settlement. The importance of seawater temperature to larval
survival may therefore be one of the factors leading to the latitudinal gradient of brachyuran
species numbers with 54 known from the English Channel and only two from Svalbard.
Increased seawater temperatures are likely to have an adverse effect on breeding in species
that require a low temperature ‘trigger’ to reproduce. For instance, Hutchins (1947)
suggested that the southern limits of distribution of the barnacle Semibalanus balanoides1
was limited by the isotherm of the minimum monthly mean surface temperature of 7.2ºC and
suggested that if the winter temperature failed to fall below that temperature, the species
was unable to breed.
Increased temperature is not thought likely to have an immediately adverse effect on sessile
or sedentary species that are already established. Long-lived species with a predominantly
northern distribution are likely to persist as adults long after they have ceased to reproduce
successfully in the locality. However, it is possible that higher levels of insolation and/or air
temperatures may kill some northern intertidal species.
1
Species names are those used in Howson & Picton (1997) where authorities can be found.
17
A reduction in the frequency of cold winters is also likely to be important in allowing survival
of established populations, although, conversely, warmer summer temperatures may also
have adverse effects. For instance, species adversely affected by the cold winter of 1962-63
(Crisp, 1964) are likely to be ones that will survive further north than at present if milder
winters prevail. Species that are adversely affected by significant warming (especially in the
intertidal) may become less abundant as a result of mortality in warmer or brighter
conditions.
Recovery rates for species after losses due to cold climatic events may also suggest the rate
at which colonisation of previously colder locations might occur. Where these observations
are documented, they have been incorporated into the detailed assessments of likely rate of
change in species distributions.
7.
LIKELY EFFECTS OF CLIMATE CHANGE ON SPECIES
7.1
Introduction
The list of species that have good distributional records and have climatically restricted
distributions in Scotland is given in Appendix 4.
Our study suggests that the following scenarios of change or stability in response to current
climate change expectations are likely to occur:
1. Boreal-arctic species at the southern limits of their range in Scotland where higher
temperatures will make reproduction or survival difficult will decline or disappear (those
extending south may be restricted to a few northern or eastern locations).
2. Species at the northern limits of their range in Scotland where higher temperatures will
make reproduction more likely or frequent or will improve prospects for larval survival will
increase in abundance and extend in their distribution providing that they are not
prevented by biogeographical or hydrographical barriers.
3. Some species may decline or increase in abundance because their grazers or predators
increase or decline in abundance. If those species are characterising or keystone
species in biotopes, the biotopes may be substantially altered.
4. Species that do not currently occur in Scotland because they are southern species
requiring higher temperatures to breed will extend to Scotland only if their life history
characteristics allow extension of range across significant biogeographical or
hydrographical barriers.
5. Changes will be most apparent first in mobile species such as fish.
6. Amongst benthic species, response will be greatest in those with a planktonic stage in
their life history.
7. Change is likely to be particularly marked in enclosed waters where increased local
warming may occur.
8. Increased surface warming may isolate more frequently the deeper parts of some
enclosed water bodies where a thermocline forms behind a sill, leading to
deoxygenation.
9. There may be locations where sea level rise will introduce seawater into currently fresh
water habitats creating new brackish water habitats.
10. Increased storminess may shift communities, particularly intertidal communities, to those
characteristic of more wave exposed conditions.
Southern species that already occur in Scotland and have life cycles that include a
planktonic phase are likely to extend their distributional limits northwards and increase in
abundance within their present range. However, those southern species that currently
18
extend to NE Ireland or to North Wales and/or NW England, will only extend to the coast of
Scotland if currents are favourable and there are no geographical barriers.
7.2
Effects of increase in air temperatures on open shore species
Algae
Many of the intertidal algae characteristic of Scottish shores occur extensively further south
(and north) of Scotland suggesting that they are unlikely to be adversely affected by
increased temperatures of the scale currently envisaged. However, higher temperatures
and increased insolation than at present could cause mortality in some northern species with
subsequent effects on the zonation of shore species. For instance, exposed rocky shores
on Fair Isle have an algal zonation with bands of macroalgae growing at up to 8 m above
sea level, although the tidal range is only about 2 m (Burrows et al., 1954). This extensive
distribution of algae up the shore was attributed to a combination of continual swell and
damp climatic conditions. If conditions become less damp, zonal extent might decrease.
Similarly, high shore ephemeral algae (for instance, Porphyra spp., Prasiola stipitata,
Enteromorpha spp., Blidingia spp.) are likely to occur for less of the year and be absent for
most of the summer (Hawkins & Hartnoll, 1983). However, increased air temperatures are
unlikely to have either an adverse or a positive effect on the occurrence and abundance of
most intertidal algae. If increased storminess occurs, extension of zones landwards might
occur or at least the adverse effects of increased dessication might be offset.
Animals
Increased air temperatures may result in mortality of some species in some years and
therefore reductions in abundance or distributions. For instance, Bowman (1978) observed
that ‘overheating’ in upper shore pools and on open rock in 1976 (a particularly hot summer)
had resulted in loss of limpets, Patella vulgata, on the north coast and elsewhere in
Scotland.
Conversely, some species might be more likely to survive if the coldest winter temperatures
become less severe. For instance, the snakelocks anemone Anemonia viridis is susceptible
to low temperatures (Crisp, 1964) and may survive and spread to new locations as adult
individuals as a result of mild winters. For other species, development of gonads might be
favoured by increased air temperatures so that fecundity increases.
7.3
Effects of increased air temperatures on species in enclosed waters
Some of the habitats for which Scotland is most important in a European context are the
shallow landlocked lagoonal habitats including the obs in the Hebrides and fjardic sea lochs
such as Loch Maddy. Several of these locations are cSACs.
There is a possibility that surface or near-surface waters in enclosed habitats with deep
water may warm sufficiently to create a thermocline strong enough to isolate bottom waters,
causing de-oxygenation. It is likely that only a few habitats may be affected in this way as
Scottish inshore waters are mainly subject to strong tidal streams and therefore mixing of the
water column. However, there are situations where occasional de-oxygenation events are
known to occur (for instance at the head of Sullom Voe (Pearson & Eleftheriou, 1981), Loch
Obisary (Mitchell et al., 1980)) and such events might become more frequent or occur for the
first time in some new locations. Such locations would be those having a sill that isolates the
deeper water.
7.4
Effects of increased air temperatures on surface waters and intertidal isolated
water bodies (rockpools)
It is most likely that milder winter conditions may help survival of species in rockpools.
Species such as blennies and gobies and the sea anemone Anemonia viridis may remain in
pools for a longer period of the year rather than moving to deeper water for winter. Several
species extend towards their northern limits primarily in pools rather than the open shores
19
and include the algae Cystoseira tamariscifolia and Bifurcaria bifurcata and the limpet
Patella ulyssiponensis. Their extension northwards as a result of climate warming will
therefore be initially in pools. The alga Fucus distichus subspecies distichus occurs in upper
shore rockpools on very wave exposed coasts and does not extend further south than the
13ºC summer isotherm. However, experimental studies (see Appendix 7) suggest that it
may be day length rather than temperature that determines reproduction and survival so that
this ‘obvious’ candidate for decline may not.
7.5
Effects of increase in seawater temperatures
Widescale effects including increased abundance and extension of distribution of southern
species alongside reduced abundance and retreat in the distribution of northern species are
the most likely effects of increased seawater temperatures across the continental shelf.
However, the rate at which change occurs and whether any change occurs will vary greatly
from species to species. Amongst species living on or near the seabed, fish are likely to
react most in concert with temperature change as they are mobile. Crustaceans will also
respond fairly rapidly if it is temperature that controls adult distribution. Next, benthic
species that have a long-lived planktonic larvae and which reproduce frequently will, in the
case of southern species, extend their distribution rapidly. Finally, species with a short-lived
larva or which reproduce asexually and do not have a mobile phase will increase in
abundance where they occur at present but be slow to extend northwards. Also, such
species may not make the jump across geographical barriers such as the North Channel
between Northern Ireland and Scotland, the Pentland Firth to Orkney or the Fair Isle
Channel to Shetland. Rate of retreat of northern species will be very dependant on the
longevity of existing individuals with probably long-lived species such as the sea anemone
Bolocera tuediae persisting for many tens of years even if reproduction has ceased. Others,
such as the limpet Tectura testudinalis, which most likely lives for only a few years, will
disappear more quickly.
7.6
Biotic interactions
Several keystone or dominant seabed species are likely to be affected by seawater warming.
‘Keystone’ species are ones which, through their predatory activities (for instance, grazing by
sea urchins or limpets), or by mediating competition between prey species (for instance, by
eating sea urchins), maintain community composition and structure. The term is also applied
here to species which provide a distinctive habitat (for instance a bed of the horse mussel
Modiolus modiolus, beds of fucoid algae, a maerl bed) and whose loss would therefore lead
to the disappearance of the associated community. Other species dominate the seabed and
define particular biotopes without being’ keystone’ and include, for instance, barnacles. In
some cases, loss of a particular species may not be significant in terms of provision or
maintenance of habitat and the continued presence of a particular biotope. For instance,
loss of the northern sea urchin Strongylocentrotus droebachiensis would most likely be
compensated for by increased abundance of the common sea urchin Echinus esculentus so
that grazing would continue. Expansion of Paracentrotus lividus would produce a new and
more efficient grazer into a habitat without such a species. Reduction in abundance of the
cold water barnacle Semibalanus balanoides would be compensated for by increased
abundance of Chthamalus spp. However, if the abundance of some species such as the
horse mussel decined, there may be significant effects on the associated fauna and flora. In
the case of loss of horse mussel beds, the biotope would most likely change to a
sedimentary one.
A most important effect of climate change might be to alter the abundance and quality of
meroplankton organisms that are important as food to other marine life. For example, the
cold water barnacle, Semibalanus balanoides, releases its larvae in synchrony over a short
period in the spring, late March to early May depending on latitude. In early spring the
nauplii can be numerically dominant in the plankton, prior to the spring outburst of copepods.
20
They may constitute an important food for larvae and juvenile stages of spring spawning
herring, gadoids and other fish, especially in enclosed bays and lochs. If Semibalanus
balanoides is replaced by Chthamalus as the dominant barnacle, this resource is lost.
Chthamalus breeds over a longer period in summer, with successive broods, at a time when
other zooplankton species are available to the young fish and other animals that feed on
plankton. Similar considerations may apply to meroplanktonic larvae of other animals, such
as the zooea larvae of crabs and prawns that can be very abundant in the spring (see
Lindley, 1998). Such effects of climate change are much more difficult to observe and to
take into account than conspicuous events in shore or sublittoral seabed organisms but are
important to take into account when predicting or accounting for change.
8.
DEVELOPING A ‘RULE BASED’ SYSTEM FOR ASSESSING LIKELY EFFECTS
FOR A PARTICULAR SPECIES
8.1
Components
The rate of geographical extension or reduction of distributional extent or change in the
abundance of species at existing locations in response to increases or decreases in
temperature are likely to be determined by:
1. Mobility of existing populations – can they swim, drift or walk or are they dependent on
larval distribution?
2. Presence of viable populations for the production of larvae – ‘relict’ populations or
populations that have recruited from distant sources and do not produce gametes, or
populations where individuals are too widely separated for gametes to meet may not be
reproductively viable and so not be a source for distributional extension.
3. Type of reproductive and dispersal mechanisms – sessile or sedentary benthic species
which reproduce asexually or that have a benthic or short-lived larval/juvenile stage will
extend their distributions less rapidly than those with long-lived planktonic propagules,
but may persist longer in the face of adverse conditions.
4. Survival of larvae in relation to water temperature – some larvae require threshold
temperatures to develop to a final settlement stage and will perish if those temperatures
are not reached.
5. The presence of suitable habitats for settlement within the potential extension of range
according to mobility of dispersive stages.
6. Lethal temperature limits of adults – in the case of lower temperatures, some adults may
perish in the winter or not reproduce if they require warm water for maturation of gonads.
In the case of higher temperatures, some species that require a low temperature trigger
to reproduce may fail or some might be killed by high temperatures.
7. Presence or absence of geographical barriers to potential spread (for instance, offshore
currents may sweep larvae away from suitable inshore habitats).
8. The presence of favourable currents to enable spread (residual currents in the direction
of temperature increase, occasional fast currents bringing larvae from distant sources).
9. Longevity of individuals in existing populations – if climate changes ‘shuts-down’
reproduction and therefore local recruitment, existing populations will persist until the end
of their natural life span is reached.
A variety of scenarios are likely and the key and decision tree given below can be applied to
a wide range of species.
21
8.2
Mechanisms - effects for southern species in a temperature rise scenario
1. Free-swimming species – likely to respond immediately – their distribution is likely to
‘track’ changes in temperature isotherms for critical temperature ranges (i.e. whether
they require warm waters in summer or cannot tolerate cold waters in winter). For
example, red mullet Mullus surmuletus, John Dory Zeus faber, cuttlefish Sepia officinalis
would all extend their distributions in Scotland due to warmer seawater temperatures.
2. Sedentary or sessile species with long-lived planktotrophic larvae – more larvae are
likely to be produced leading to an increased abundance of the species locally and the
possibility of extension of range. For example, the purple sea urchin Paracentrotus
lividus.
3. For sedentary or sessile species that reproduce asexually or have short-lived larvae,
abundance is likely to increase at the locations where the species already occurs.
Extension of range will occur through individuals detaching from the substratum or larvae
being carried (usually short distances) in the water column. Few species are likely to
detach and float away, an exception being the snakelocks anemone Anemonia viridis.
Occasional ‘jetstream’ currents at the time of detachment or reproduction may take
individuals or short-lived larvae a considerable distance so that, providing suitable
habitats are present, there will be a gradual extension of range (for example, larvae of
the snakelocks anemone Anemonia viridis and the sea fan Eunicella verrucosa).
8.3
Mechanisms - effects for northern species in a temperature rise scenario
1. Species that are free swimming or walking are likely to respond immediately and retreat
from the pre-existing southern limits of their range. For instance, the northern stone crab
Lithodes maia, the viviparous blenny Zoarces viviparus.
2. Sedentary or sessile species are likely to remain present for as long as adults live but
recruitment is unlikely to occur. For instance, the tortoiseshell limpet Tectura testudinalis,
the sea urchin Strongylocentrotus droebachiensis.
Exceptions to the above two scenarios may occur where populations are isolated by barriers
such as the sills of sea lochs and where deeper waters maintain conditions where
reproduction and settlement continues (for instance, in case of the arctic relict bivalve
mollusc Thyasira gouldii: Blacknell & Ansell, 1974; Southward & Southward, 1991). Species
that reproduce asexually as well as sexually such as many sea anemones may continue to
produce new individuals even though larvae are not being produced (may include the cold
water anemone Bolocera tuediae).
Some species that may be expected to decline in abundance as a result of temperature rise
may be restricted in their distribution for reasons other than temperature and may persist.
For instance, with the exception of the St Kilda population, the brown seaweed Fucus
distichus distichus does not occur south of the summer 13°C isotherm in Britain. A simplistic
extrapolation from the present distributional range would suggest that following a 1°C and
2°C rise in summer sea temperature the 13°C isotherm would have moved north of the
British Isles and Fucus distichus distichus would therefore become extinct in Britain.
However, laboratory and autecological field studies indicate that mature Fucus distichus
distichus plants can tolerate higher temperatures (McLaclan, 1974; Bird & McLaclan, 1976).
Embryos also develop at 15°C (and higher). A critical factor is probably daylength; short
daylengths stimulate the onset of receptacle formation and this will not change with global
warming. Bird & McLachlan (1976) showed that the formation of receptacles was
independent of temperature but maturation progressed with increasing temperature to at
least 15°C. It is a possibility that a 2°C rise in sea temperature may make no difference to
the populations of Fucus distichus distichus in northern Scotland. Stormier sea conditions
(predicted as a result of global warming) and competition from other marine organisms may,
however, do so. Why Fucus distichus distichus does not occur more widely in Britain, as
22
could be inferred from laboratory and autecological studies (and also shown by subspecies
anceps) remains unclear.
8.4
Mechanisms – the importance of residual currents.
Residual currents are those that carry water masses (including larvae or passively
transported adults) in a particular direction and are indicated after the ebb and flow of tidal
currents are removed from records. There are a number of fixed current meters established
around the Scottish coast which indicate daily, seasonal and annual changes. Tracking the
movement of radioactive contaminants from the Sellafield nuclear reprocessing plant in
Cumbria has also provided valuable insights into the long-term movement of water masses.
For instance, the movement of radiocaesium discharged from Sellafield suggest a residual
flow northwards along the west coast of Scotland of about 1.7 km a day (Economides,
1989). Occasional ‘jetstream’ currents which might especially occur along shelf sea fronts
may be important. These ‘jetstreams’ are partly apocryphal but Simpson et al. (1979) found
residual current velocities of 20 cm/s parallel to the Islay front which would be approximately
equivalent to movement of water with passive larvae of about 10 km in one direction in one
day.
8.5
Exceptions - localised effects in isolated waters
There are several locations in Scotland where poor water exchange with sheltered water
bodies may result in localised warming (if temperatures rise) in shallow or surface waters.
Two significant effects are likely:
1. Shallow waters may be come more amenable to ‘blooms’ of species that thrive in warm
water during the summer. Such species include the non-native alga Sargassum
muticum and possibly some fish such as Ctenolabrus rupestris.
2. Where the isolated waters have a shallow sill or are sluiced, deeper waters may become
isolated through thermal stratification during summer and consequently become
deoxygenated.
8.6
The ‘key’ - determining the likely effects of temperature increase on a particular
species
The following key and description of types assumes an increase in air and seawater
temperatures and is based on the components described above.
1.
2.
3.
The species is pelagic (swims or drifts in the water column) …………………
2
The species is sedentary or sessile (attached to or crawling on the seabed)
3
The species is northern in distribution …………………………………………...
Type A
The species is southern in distribution ….……………………………………….
Type D*
The species has a planktonic distributional phase …………………………….
4
The species has a benthic larva, very short lived (a few hours) pelagic
phase or reproduces asexually …………………………………………………...
4.
The species are long-lived (>5years) and likely to reproduces infrequently or
not at all, at least at its geographical limits. (“infrequently” means only every
few years) ………………………….…………………………………………….
23
5
Type F*
The species is short-lived (<5 years) and currently reproduces frequently
(usually once a year and over a prolonged period) .………………………….
5.
6.
7.
8.
9.
6
The species currently reproduces infrequently or not at all, at least at its
geographical limits. (“infrequently” means only every few years) …………….
7
The species currently reproduces frequently (usually once a year and over a
prolonged period) .………………………………………………………………….
8
Species is northern in distribution ………………………………………………..
Type C
Species is southern in distribution ……………………………………………….
9
Species is northern in distribution ………………………………………………..
Type B
Species is southern in distribution ………………………………………………..
Type E
Species is northern in distribution ………………………………………………..
Type C
Species is southern in distribution ………………………………………………..
Type E
The species occurs in populations sufficiently dense or close so that
gametes will meet.
Type G*
The species occurs as isolated individuals and gametes are unlikely to meet
OR the species occurs at isolated locations or habitats where other suitable
locations or habitats are likely to be too distant for propagules to reach.
Type E
* Use the decision tree that follows (Figure 7) to determine importance of barriers to spread.
Type A (northern volatiles)
Species that are pelagic or demersal (such as plankton and fish) where the adults respond
rapidly to temperature change. Significant changes will occur in relation to annual variations
in temperature with an overall reduction in abundance and ‘retreat’ northwards over the next
50 years.
Type B (northern stables)
Species that currently have a northern distribution that will ‘retreat’ northwards but very
slowly as individuals are long-lived and recruit irregularly. Reproductive success at current
southern limits will be reduced as a result of higher temperatures. Decline in abundance at
southern limits but no significant change expected in distribution in the next 50 years.
Type C (northern ‘retreaters’)
Species that currently have a northern distribution which will decline in abundance and
‘retreat’ northwards rapidly (in ‘concert’ with isothermal changes), are short-lived (<5years)
and rely on regular recruitment from the plankton or from benthic larvae. The speed of
change in abundance and distribution might fluctuate depending on the occurrence of
24
particularly warm years. Significant reductions in abundance and distributional extent are to
be expected in the next 50 years.
Type D (southern volatiles)
Species that are pelagic or demersal (such as plankton and fish) where the adults respond
rapidly to temperature change. Significant changes will occur in relation to annual variations
in temperature with an overall expansion in distribution northwards and increase in
abundance within their present limits over the next 50 years.
Expansion of distribution northwards may be prevented or slowed by geographical barriers
such as locations where currents sweep offshore or extensive areas where favoured
(demersal) habitats are absent.
Apply Figure 7, the water currents and quality decision tree.
Type E (southern stables)
Species that currently have a predominantly southern distribution which will expand
northwards or become more abundant within their present range but slowly. Individuals are
long-lived and reproduce infrequently by benthic or short lived larvae or by asexual division.
Reproductive success at current northern limits of distribution will improve as a result of
higher temperatures. Abundance of individuals will increase at locations where they are
already found. Northward extent will increase very little in the next 50 years and not at all
where significant geographical barriers exist.
Type F (southern gradual extenders)
Species that currently have a predominantly southern distribution that will expand
northwards and increase in abundance at their current locations and in a sporadic way
dependent on particularly favourable years for reproduction. The species currently
reproduce infrequently at least at their geographical limits but have a planktonic larva. There
will be a ‘lag’ period between temperature increase and expansion in abundance or northern
extent.
Expansion of distribution northwards may be prevented or slowed by geographical barriers
such as locations where currents sweep offshore or extensive areas where favoured habitats
are absent.
Apply Figure 7, the water currents and quality decision tree.
Type G (southern rapid extenders)
Species that currently have a predominantly southern distribution which will expand
northwards at about the same rate as isothermal changes in sea or air temperatures
providing that currents are favourable and there are no barriers to spread. Species will
become more abundant within their present range.
Expansion of distribution northwards may be prevented or slowed by geographical barriers
such as locations where currents sweep offshore or extensive areas where favoured habitats
are absent. Water quality may also be important in determining whether or not larvae settle
and survive. The decision tree below is for species that have the ability to spread (Types D,
F, G).
Apply Figure 7, the water currents and quality decision tree.
25
Figure 7: Water currents and quality decision tree for southern species.
Are currents in a
favourable direction
for larvae to spread
in direction of
increased
temperature?
Yes
No
Are there suitable
habitats downstream
of existing
populations within
reach of larvae?
Extension of
distribution will be
slow or not occur
but size of local population will expand
No
Yes
Extension of
distribution to distant
habitats may rely on
infrequent ‘jet
streams’ when
larvae are present or
not occur
Will existing
‘water
quality’
(fertility)
support
survival of
larvae to
reach new
habitats?
No
Recruitment to new
areas may rely on
infrequent
occurrence of the
‘right’ water quality.
Yes
Colonisation of new
areas will occur at
a rate matching
increase in water
temperature.
9.
EXAMPLES OF POSSIBLE CHANGE
9.1
Likely effects on representative species
A potentially large number of species will be affected by climate change. Representative
species have been selected based on the likelihood that their distribution and abundance will
change, complementarity (similar species representing northern and southern distributions),
and their suitability for monitoring studies. Detailed study has been undertaken for 23
species (see Table 1 for the species selected and Appendix 7 for conclusions).
Temperature change has been taken as the most important factor determining changes in
distribution and abundance. No attempt has been made to predict localised changes in
26
temperature and the present isotherm lines have been used to represent 1ºC and 2ºC rises
in temperature. However, winter or summer isotherms have been used depending on which
it is thought might be most important in determining current distribution patterns.
9.2
Likely effects on susceptible biotopes
Biotopes likely to be changed or lost as a result of climate change are those where key
characterising or structuring species may be affected by seawater warming. The biotopes
identified as likely to change in distribution and extent as a result of temperature rise are
listed with reasons for inclusion in Appendix 5. Those for which an assessment of current
distribution and likely effects has been undertaken, including some from the list of biotopes
included in statutes and directives (Appendix 3), are marked in Appendix 5 and conclusions
are given in Appendix 7.
Not all biotopes that appear likely to be adversely affected by warmer conditions or higher
levels of insolation will change. For instance, biotopes dominated by foliose algae or by the
kelp Alaria esculenta are known to spread further up the shore (to conditions where
desiccation is more severe) if grazers are removed. There may be some adverse effects on
such lower shore biotopes including more frequent bleaching events but overall decline in
distribution is not expected in Scotland. Also, species currently restricted to rockpools but
which dominate open shore areas in southern Europe (Bifurcaria bifurcata and Cystoseira
species especially) are not expected to expand in abundance to such an extent that they
take-over open shores in Scotland. Similarly but conversely, it is not expected that
temperature change will be sufficient in Scotland to reduce abundance or extent of the coldwater kelp Alaria esculenta which is dominant in some lower shore and shallow sublittoral
biotopes on exposed coasts in Scotland, although decline in south-west England and Wales
is expected. It is difficult to predict if there might be any adverse effects on the distinctive
rock biotopes present in Scottish sea lochs as little is known of the biology of key component
species such as the brachipod Neocrania anomala and the sea anemone Protanthea
simplex. A similar lack of knowledge of biology makes it difficult to predict likely effects on
the deep burrowing megafauna communities of sea lochs or the reefs of the tube worm
Serpula vermicularis. However, as reefs of Serpula are also known from Killary Harbour in
southern Ireland, it might be expected that they will withstand higher temperatures. No
intertidal sediment biotopes are identified as likely to be subject to decline or loss or to
appearance and spread in Scotland.
10.
LOCATIONS WHERE CHANGE MIGHT BE PARTICULARLY ACUTE
Change may be particularly acute at open coast locations or in enclosed areas with high
water exchange where self-recruiting but small populations of southern species already
occur and will increase in abundance to dominate habitats. Conversely, in open coastal
areas or in enclosed areas with high water exchange where present cold waters prevail,
reduced abundance of cold water species such as the horse mussel Modiolus modiolus may
greatly affect the communities that develop within the beds or clumps that they form.
Change would most likely occur first in those communities that are naturally variable, with
turnover moving towards southern species dominating.
Warming of surface waters of enclosed areas such as sea lochs with a sill and low water
exchange or the obs in the Hebrides may have two significant effects:
•
Warmer shallow waters will encourage reproduction and increase in abundance of
southern species currently of low abundance.
•
There will be a larger difference between warm surface waters and cold deeper waters
increasing thermal isolation of deeper waters and causing deoxygenation for extended
periods or more frequent and longer periods of deoxygenation where episodes already
occur.
27
Figure 8: Location of proposed and candidate SACs in Scotland (map supplied by SNH,
square brackets added to indicate sites without seabed habitats).
11.
RELEVANCE TO SCOTTISH SACs
Candidate SACs are distributed all around the Scottish coast (Figure 8) and form a
potentially useful, although not exclusive, network for monitoring changes in the distribution
of biotopes and species and the abundance of species populations. Although many of the
designations are based on non-benthic criteria (e.g. seals at Mousa, dolphins in the Moray
Firth) these sites will be of use in benthic monitoring. They will also encompass most of the
major biotopes.
28
The Solway Firth SAC will be of particular value in monitoring Sabellaria alveolata. The
network of west coast SACs should encompass most of the species likely to change. SACs
in Orkney and Shetland will be of value in monitoring species like Strongylocentrotus
doebachiensis which may well disappear from Scotland. Some south and western species
are likely to extend around the north east corner of Scotland and increase in abundance on
North Sea coasts. Therefore the SACs on the east coast could be employed here –
although coverage is currently poor.
12.
RECOMMENDATIONS FOR FUTURE ACTION BY SNH
The years 2000 to 2005 should be a baseline against which future changes in the
distribution and abundance of species and the distribution and extent of biotopes are
assessed.
Some species will require specialist recording (for instance of the barnacles Chthamalus
stellatus and Chthamalus montagui, species of the limpet Patella and trochid snails) by
experienced marine biologists. Abundances of the animals should generally be expressed
using a semi-quantitative logarithmic scale such as that described by Crisp & Southward
(1958) or the MNCR abundance scale (Hiscock, 1996). At key stations, the critical species
of barnacles, limpets and top shells should be counted in replicated quadrats using stratified
random sampling with within site nesting of replicate sets of quadrats. The quadrat size is
correlated with the abundance of the species: 5cm x 5cm to 50cm x 50cm for the barnacles,
50cm x 50cm to 1m x 1m for limpets and topshells. Appropriate methods are given in
Hawkins & Jones (1992) and are currently being developed for monitoring in Special Areas
of Conservation (SAC) (see www.english-nature.org.uk/uk-marine).
For many species, a more general descriptive approach might be adopted both on the shore
and underwater, but still at specific locations. Accuracy of identification and care in the use
of abundance scales is essential but the surveys should be aimed at searching for
appearances and disappearances rather than declines and increases in abundance.
Although targeted and repeatable survey at particular locations is required, a more general
observation scheme should be launched so that records can be logged from wherever
observations are made. The scheme would be focussed on species that are easily
recognised and include a high proportion of ones that may be subject to climate change
effects. The scheme would be co-ordinated by a Scottish institute but also contribute to UK
or Britain and Ireland projects and contribute information to the UK National Biodiversity
Network. The scheme can be Web-based and such a project is already demonstrated on
www.marlin.ac.uk/wwf (the WWF-UK ORCA programme). A modification of the Seasearch
programme would achieve such recording and further development of volunteer recording
under the activities of the National Biodiversity Network is planned. Some studies such as
the SAC monitoring surveys are already underway but may need to be adjusted to ensure
that species that are likely to change (and that are noted in this report and the Phase 1
report) are especially targeted for detailed survey.
There are locations around the Scottish coast that could be used for targeted recording
exercises. Table 3 is an initial proposed list of locations with explanation of why they have
been selected. As far as possible, locations have been suggested because historical data or
at least knowledge exists for them. However, many reasons are of a practical (access)
nature and some depend on presence of local expertise. There is an opportunity to combine
climate change effects monitoring with the studies required to report on the conservation
status of SACs. It is expected that the list will be substantially modified after discussion with
marine biologists with a thorough knowledge of Scotland and a meeting of those biologists
should be organised to determine sites and methods.
29
Table 3. Initial proposed list of locations around the Scottish coast that could be targeted for
establishing a baseline and recording change in species abundance and presence in relation
to climate change. Sites that are known to be in proposed or candidate SACs are
emboldened.
Location
Southerness Point, Solway
Port Patrick, Galloway
Burrow Head, Galloway
Intertidal
+
+
+
Mull of Galloway (E. side)
Cumbrae (Connell’s sites)
+
Subtidal
+
East side of Cumbrae
Loch Fyne
+
+
Tip of the Kintyre peninsula (at
lighthouse?)
Caol Scotnish (Loch Sween)
Ardnoe Point, Crinan
+
Easdale
+
Open coast of Mull incl. Iona
+
Tiree
Loch nam Umah
Ardnamurchan Peninsula
Eigg
Rudh Arisaig
+
+
+
+
+
+
+
Sound of Arisaig
+
Loch Duich
+
Strome Narrows, Loch Carron
+
Skye, Point of Sleat and
Trumpan Head
Rudha Reid, north of Gairloch
+
+
Point of Stoer/ Scourie
+
Borve Point, Barra
+
Barra/South Uist sandy
beaches
Loch Eyenort
Harris and Lewis, Husinich,
Carloway, Butt of Lewis
Balnakeil Bay
+
+
+
+
30
Notes
Sabellaria alveolata colonies.
Barnacles and limpets.
Barnacles and limpets (area of inshore
warming in summer)
Southern Anthoza.
Barnacles and limpets including Tectura
testudinalis. Gibbula umbilicalis.
Southern Anthoza.
Northern species and species
characteristic of sea loch.
Barnacles and limpets, Chthamalus
stellatus especially. Gibbula umbilicalis.
Lithothamnion glaciale maerl beds.
Southern v. northern species in the
‘Erect sponges and Swiftia pallida’
biotope.
Barnacles and limpets. Gibbula
umbilicalis.
Barnacles and limpets Gibbula
umbilicalis.
Dictyopteris membranacea
Codium adhaerens
Paracentrotus lividus
Paracentrotus lividus
Barnacles and limpets. Gibbula
umbilicalis.
Maerl, Phymatolithon calcaereum,
beds and component species.
‘Classic’ rock and sediment sealoch
biotopes.
Southern v. northern species. Modiolus
and maerl beds. Long-term records
available.
Barnacles and limpets. Gibbula
umbilicalis. Paracentrotus lividus.
Barnacles and limpets. Gibbula
umbilicalis.
Barnacles and limpets. Gibbula
umbilicalis.
Barnacles and limpets. Gibbula
umbilicalis.
Sabellaria alveolata.
Southern Anthozoa.
Barnacles and limpets. Gibbula
umbilicalis.
Sabellaria alveolata.
Loch Eriboll (entrance)
Faraid Head, Durness
Strathy Point
Dunnet Head
Duncansby Head
Brough Head, Orkney
+
+
+
+
+
+
Scapa Flow, Orkney
Scatness, Shetland
Ronas Voe, Shetland
+
+
+
Skaw Taing, Sullom Voe,
Shetland
Bressay Sound, Lerwick,
Shetland
Wick
+
Brora
+
Portknockie
+
Kinnairds Head
+
Peterhead
+
Garron Point, Stonehaven
+
Arbroath
+
Fife Ness
+
Isle of May
St Abbs / Eyemouth
+
St Abbs / Eyemouth
+
+
+
+
Southern Anthozoa.
Barnacles and limpets.
Barnacles and limpets.
Barnacles and limpets.
Barnacles and limpets.
Barnacles and limpets. Gibbula
umbilicalis.
Southern Anthozoa. Cucumaroa
frondosa (in sounds).
Barnacles and limpets.
Deep sheltered rock – southern
Anthozoa.
Modiolus beds and associated species.
(History of study.)
Cucumaria frondosa and
Strongylocentrotus droebachiensis.
Barnacles and limpets. Gibbula
umbilicalis.
Barnacles and limpets. Gibbula
umbilicalis.
Barnacles and limpets. Gibbula
umbilicalis.
Barnacles and limpets. Gibbula
umbilicalis.
Barnacles and limpets. Gibbula
umbilicalis.
Barnacles and limpets. Gibbula
umbilicalis.
Barnacles and limpets. Gibbula
umbilicalis.
Barnacles and limpets. Gibbula
umbilicalis.
Northern fauna.
Barnacles and limpets. Gibbula
umbilicalis.
Northern fauna
There are various baselines of biological information that can be used to identify any change
in the distribution and abundance of species. They include the records of commercial
species of fish maintained by Fisheries Research Services in Aberdeen, records collected
during monitoring exercises linked to the National Marine Monitoring Programme and to SAC
management, the results of survey and monitoring in Shetland and Orkney linked to the oil
terminals there, and the results of single surveys such as the MNCR series. There is also
much anecdotal and unpublished information that needs to be reviewed and curated.
Much unpublished information is available which needs to be rescued and archived properly
to contribute to the establishment of a baseline of current and recent distributional
information. Initiatives taken after the commencement of the project described in this report
will develop work on climate change effects on marine species and biotopes in Britain and
Ireland. The new work will link to the climate change project MONARCH (Modelling Natural
Resource Responses to Climate Change) which is appraising the impact of climate change
on:
1. changes in coastal processes, in particular the impact of the relocation of sediments,
changes in water temperature and sea-level rise on the availability of benthic
invertebrates for local bird popluations;
31
2. seven Biodiversity Action Plan (BAP) priority habitats on changes in ocean temperatures
and other variables, indicating possible future relocations. The habitats are chalk reefs,
maerl beds, Serpula vermicularis reefs, Sabellaria alveolata reefs, Sabellaria spinulosa
reefs, Modiolus modiolus beds and Lophelia pertusa reefs.
13.
REFERENCES AND BIBLIOGRAPHY OF RELEVANT LITERATURE
Adkins, J. F., Boyle, E. A., Keigwin, L. & Cortijo, E. (1997). Variability of the North Atlantic
thermohaline circulation during the last intergalcial period. Nature, 390, 154-156.
Aebischer, N. J., Coulson, J. C. & Colebrook, J. M. (1990). Parallel long-term trends across
4 marine trophic levels and weather. Nature, 347, 753-755.
Anon. (1999). UK Biodiversity Group Tranche 2 Action Plans. Volume V - maritime species
and habitats. Department of Environment Transport & the Regions, London.
Ansell, A. D. & Robb, L. (1977). The spiny lobster Palinurus elephas in Scottish waters.
Marine Biology, 43, 63-70.
Bard, E., Arnold, M., Duprat, J., Moyes, J. & Duplessy, J. C. (1987). Reconstruction of the
last deglaciation: deconvolved records of d18O profiles, micropalaeontological
variations and accelerator mass spectrometric 14C dating. Climate Dynamics, 1, 101112.
Barnes, H. & Barnes, M. (1977). The importance of being a "littoral" nauplius. In Biology of
Benthic Organisms (eds. B. F. Keegan, P. O'Ceidigh & P. J. S. Boaden), pp 45-56.
Pergamon Press, Oxford,.
Barry, J. P., Baxter, C. H., Sagarin, R. D. and Gilman, S. E. (1995). Climate-related, longterm faunal changes in a California rocky intertidal community. Science, 267, 672675.
Baxter, J. M., Jones, A. M. & Simpson, J. A., (1985). A study of long-term changes in some
rocky shore communities in Orkney. Proceedings of the Royal Society of Edinburgh,
75, 47-63.
Baxter, J. M. & Usher, M. B., (1994). The Islands of Scotland. H.M.S.O., Edinburgh.
Bird N.L. & McLachalan J. (1976). Control of formation of receptacles in Fucus distichus L.
ssp. distichus (Phaeophyceae: Fucales). Phycologia, 15, 79-84.
Blacknell, W. M. & Ansell, A. D. (1974). The direct development of Thyasira gouldi (Phillipi).
Thalassia Jugoslavica, 10, 23-43.
Bowman, R.S. (1978). Dounreay oil spill: major implications of a minor incident. Marine
Pollution Bulletin, 9, 269-273.
Bowman, R. S. & Lewis, J. R. (1986). Geographical variation in the breeding cycles and
recruitment of Patella spp. Hydrobiologia, 142, 41-56.
Broecker, W. S. (1997). Will our ride into the greenhouse future be a smooth one? GSA
Today (Publicaton of the Geological Society of America), 7, 1-7.
Bruce, J. R., Colman, J. S. & Jones, N. S. (1963). Marine Fauna of the Isle of Man.
University Press, Liverpool.
Burrows, E. M. (1991). Seaweeds of the British Isles. Vol. 2: Chlorophyta. British Museum
(Natural History), London.
Burrows, E.M., Conway, E., Lodge, S.M. & Powell, H.T. (1954). The raising of intertidal algal
zones on Fair Isle. Journal of Ecology, 42, 283-288.
32
Burrows, M. T. (1988). The comparative biology of Chthamalus stellatus (Poli) and
Chthamalus montagui Southward. PhD Thesis, University of Manchester.
Burrows, M. T., Hawkins, S. J. & Southward, A. J. (1992). A comparison of reproduction in
co-occurring chthamalid barnacles, Chthamalus stellatus (Poli) and Chthamalus
montagui Southward. Journal of Experimental Marine Biology and Ecology, 160, 229249.
Byrne, M. (1990). Annual reproductive cycles of the commercial sea urchin Paracentrotus
lividus from an exposed intertidal and a sheltered subtidal habitat on the west coast
of Ireland. Marine Biology, 104, 275-289.
Clark, P. F. (1986). North-East Atlantic Crabs: an Atlas of Distribution. The Marine
Conservation Society, Ross-on-Wye.
Connor, D. W., Brazier, D. P., Hill, T. O. & Northen, K. O. (1997a). Marine Nature
Conservation Review: marine biotope classification for Britain and Ireland. Volume 1.
Littoral biotopes. Version 97.06. Joint Nature Conservation Committee,
Peterborough.
Connor, D. W., Dalkin, M. J., Hill, T. O., Holt, R. H. F. & Sanderson, W. G. (1997b). Marine
Nature Conservation Review: marine biotope classification for Britain and Ireland.
Volume 2. Sub-littoral biotopes. Version 97.06. Joint Nature Conservation
Committee, Peterborough.
Cornelius, P. F. S., (1995). North-West European Thecate Hydroids and their Medusae.
Synopsis of the British Fauna (New Series), 50.
Crisp, D.J., (ed.) (1964). The effects of the severe winter of 1962-63 on marine life in Britain.
Journal of Animal Ecology, 33, 165-210.
Crisp, D. J. & Fischer-Piette E. (1959). Répartition des principales espèces intercôtidales de
la côte Atlantique Francaise en 1954-1955. Annales de l' Institut Océanographique.
Monaco, 36, 275-387.
Crisp, D.J. & Ritz, D.A. (1967). Changes in temperature tolerance of Balanus balanoides
during its life cycle. Helgoländer wissenschaftliche Meeresuntersuchungen, 15, 98115.
Crisp, D. J. & Southward, A. J. (1953). Isolation of intertidal animals by sea barriers. Nature,
172, 208.
Crisp, D. J. & Southward, A. J. (1958). The distribution of intertidal organisms along the
coasts of the English Channel. Journal of the Marine Biological Association of the
United Kingdom, 37, 157-208.
Crisp, D. J., Southward, A. J. & Southward, E. C. (1981). On the distribution of the intertidal
barnacles Chthamalus stellatus, Chthamalus montagui and Euraphia depressa.
Journal of the Marine Biological Association of the United Kingdom, 61, 359-380.
Cunningham, P. N., Hawkins, S. J., Jones, H. D. & Burrows, M. T. (1984). The geographical
distribution of Sabellaria alveolata in England, Wales and Scotland, with investigation
into the community structure of, and the effects of trampling on Sabellaria alveolata
colonies. University of Manchester, 39p.
Cushing, D. H. (1975). Marine Ecology and Fisheries. University Press, Cambridge.
Cushing, D.H., D.H. & Dickson, R.R. (1976). The biologoical response on the sea to climatic
changes. Advances in Marine Biology, 14, 1-122.
Davison, D. M. (1996). An estimation of the total numbers of marine species that occur in
Scottish coastal waters. Scottish Natural Heritage Review. No. 63. SNH, Battleby.
33
Dixon, P. S. and Irvine, L. M. (1977). Seaweeds of the British Isles. Vol. 1: Rhodophyta. Pt. 1
Introduction, Nemaliales, Gigartinales. British Museum (Natural History), London.
Economides, B. (1989). Tracer applications of Sellafield radioactivity in British west coastal
waters. PhD Thesis, University of Glasgow.
Fischer-Piette, E. (1933). Nouvelles observations sur l'ordre d'euryhalinité des especes
littorales. Bulletin de l'Institute Oceanographique, Monaco, 619, 16pp.
Fischer-Piette, E. (1936). Études sur la biogeographie intercotidale des deux rives de la
Manche. Journal of the Linnean Society. Zoology, 40, 181-272.
Fischer-Piette, E. (1937). Croissance d'espèces littorales, comparée en different types de
station. Comptes Rendus de la Societe Biogeographie, 14, 4-6.
Fletcher, R. L. (1987). Seaweeds of the British Isles. Vol. 3: Fucophyceae (Phaeophyceae).
Part 1. British Museum (Natural History), London.
Forbes, E. (1848). On the connexion between the distribution of the existing fauna and flora
of the British Isles, and the geological changes which have affected their area,
especially during the epoch of the Northern Drift. Memoirs of the Geological Survey
of the United Kingdom, 1, 336-432.
Forbes, E. (1858). The Distribution of Marine Life, illustrated chiefly by Fishes & Molluscs &
Radiata. In A.K. Johnston's Physical Atlas, pp. 99-101, Edinburgh.
Forbes, E. & Godwin-Austen, R. (1859). The Natural Hisrory of the European Seas. John
van Voorst, London.
Forbes, E. & Hanley, S. (1853). A History of British Mollusca and their Shells. London.
Foster-Smith, J., (ed.). 2000. The Marine Fauna and Flora of the Cullercoats District. (Two
volumes.) University of Newcastle and Penshaw Press.
Friedlander, M. & Ben Amotz, A. (1990). Acclimation of brown seaweeds in an outdoor
cultivation system and their cytokinin-like activity. Journal of Applied Phycology, 2,
145-154.
Garwood, P. R. & Kendall, M. A. (1985). The reproductive cycles of Monodonta lineata and
Gibbula umbilicalis on the coasts of mid-Wales. Journal of the Marine Biological
Association of the United Kingdom, 65, 993-1008.
Gerard, J. (1597). The Herball or generall Historie of Plantes.... J. Norton, London.
Harvey, L. A. (1964). A hermit crab new to Britain. Nature, London, 203, 99-100.
Hawkins, S. J. & Hartnoll, R. G. (1983). Changes in a rocky shore community: an evaluation
of monitoring. Marine Environmental Research, 9, 131-181.
Hawkins, S. J. & Hartnoll, R. G. (1985). Factors determining the upper limits of intertidal
canopy-forming algae. Marine Ecology Progress Series, 20, 265-271.
Hawkins, S. J. & Jones, H. D. (1992). Rocky Shores. Immel, London.
Hawkins, S.J., Norton, T.A. & Raffaelli, D.G. (1992). Global Climate Change and British Hard
Shores. Discussion Document Prepared for Dr R. Mitchell, JNCC. Unpublished report
to the Joint Nature Conservation Committee, Peterborough.
Hayward, P., Nelson-Smith, T. & Shields, C. (1996). Sea Shore of Britain and Europe.
HarperCollins, London.
Hayward, P. J. & Ryland, J. S. (1979). British Ascophoran Bryozoans. Keys and notes for
the identification of the species. Academic Press.
Hayward, P. J. & Ryland, J. S. (1995). Handbook of the Marine Fauna of North-West
Europe. University Press, Oxford.
34
Hayward, P.J. & Ryland, J.S., 1999. Cheilostomatous Bryozoa. Part II Hippothooidea Celleporoidea. Synopses of the British Fauna (New Series), (ed. D.M. Kermack &
R.S.K. Barnes), The Linnean Society of London. London: Academic Press.
[Synopses of the British Fauna, no. 14. 2nd edition.]
Hiscock, K., (ed.) 1996. Marine Nature Conservation Review of Great Britain. Volume 1:
Rationale and Methods. Peterborough, Joint Nature Conservation Committee.
Hiscock, K., (ed.) (1998). Marine Nature Conservation Review of Great Britain. Benthic
marine ecosystems: a review of current knowledge for Great Britain and the northeast Atlantic. Joint Nature Conservation Committee, Peterborough.
Howson, C. M. & Picton, B. E. (1997). The species directory of the marine fauna and flora of
the British Isles and surrounding seas. Ulster Museum and The Marine Conservation
Society, Belfast and Ross-on-Wye.
Hulme, M. & Jenkins, G.I. (1998). Climate change scenarios for the UK: scientific report.
UKCIP Technical Report No. 1, Climate Change Unit, Norwich.
Hunter, E., Shackley, S. E. & Bennett, D. B. (1996). Recent studies of the crawfish Palinurus
elephas in south Wales and Cornwall. Journal of the Marine Biological Association of
the United Kingdom, 76, 963-983.
Hurrell, J. W. (1995). Decadal trends in the North-Atlantic oscillation - regional temperatures
and precipitation. Science, 269, 676-679.
Hutchins, L.W. (1947). The bases for temperature zonation ingeographical distribution.
Ecological Monographs, 17, 325-335.
Ingle, R. W. (1980). British Crabs. British Museum (Natural History), London.
Irvine, L. M. (1983). Seaweeds of the British Isles. Vol. 1: Rhodophyta. Pt. 2A
Cryptonemiales (sensu stricto), Palmariales, Rhodymeniales. British Museum
(Natural History), London.
Irvine, L. M. & Chamberlain, Y. M. (1994). Seaweeds of the British Isles. Vol. 1: Rhodophyta.
Pt. 2B Corallinales, Hildenbrandiales. Natural History Museum, London.
Johnson, T. & Gerard, J. (1633). The Herball or generall Historie of Plantes.... A.J.T.Norton
& R.Whitakers, London.
Kendall, M. A. (1987). The age and size structure of some northern populations of the
trochid gastropod Monodonta lineata. Journal of Molluscan Studies, 53, 213-222.
Kendall, M. A. & Bedford, M. L. (1987). Reproduction and recruitment of the barnacle
Chthamalus montagui at Aberystywyth (mid-Wales). Marine Ecology Progress
Series, 38, 305-308.
Kendall, M. A. & Lewis, J. R. (1986). Temporal and spatial patterns in the recruitment of
Gibbula umbilicalis. Hydrobiologia, 142, 15-22.
Kendall, M. A., Williamson, P. & Garwood, P. R., (1987). Annual variation in recruitment and
population structure of Monodonta lineata and Gibbula umbilicalis populations at
Aberaeron, Mid-Wales. Estuarine, Coastal and Shelf Science, 24, 499-511.
Lamb, H. H. (1977). Climate, present, past and future, 2. Climatic history and the future.
Methuen, London.
Lamb, H. H., (1988). Weather, Climate and Human Affairs. Routledge, London and New
York.
Lee, A. J. & Ramster, J. W. (1981). Atlas of the Seas around the British Isles. Ministry of
Agriculture, Fisheries and Food.
35
Lewis, J. R. (1957a). Intertidal communities of the northern and western coasts of Scotland.
Transactions of the Royal Society of Edinburgh, 63, 185-220.
Lewis, J. R. (1957b). An introduction to the intertidal ecology of the rocky shores of a
Hebridean island. Oikos, 8, 130-160.
Lewis, J. R. & Powell, H. T. (1960). Aspects of the intertidal ecology of rocky shores in
Argyll, Scotland. I. General description of the area. Transactions of the Royal Society
of Edinburgh, 64, 45-74.
Lewis, J. R. (1964). The Ecology of Rocky Shores. English Universities Press, London.
Lewis, J. R. (1986). Latitudinal trends in reproduction, recruitment and population
characteristics of some rocky littoral molluscs and cirripedes. Hydrobiologia, 142, 113.
Lewis, J. R. (1996). Coastal benthos and global warming: strategies and problems. Marine
Pollution Bulletin, 32, 698-700.
Lewis, J. R. (1999). Coastal zone conservation and management: a biological indicator of
climatic influences. Aquatic Conservation - Marine and Freshwater Ecosystems, 9,
401-405.
Lewis, J. R., Bowman, R. S., Kendall, M. A. & Williamson, P. (1982). Some geographical
components in population dynamics: possibilities and realities in some littoral
species. Netherlands Journal of Sea Research, 16, 18-28.
Lindley, J.A. (1998). Diversity, biomass and production of decapod crustacean larvae in a
changing environment. Invertebrate Reproduction and Development, 33, 209-219.
Luning, K. (1990). Seaweeds, their environment, biogeography, and ecophysiology. John
Wiley & Sons, New York.
MacDonald, D. S. & Mills, D. L. (1996). Data storage and analysis - the MNCR database. In
Marine Nature Conservation Review: Rationale and Methods (ed. K. Hiscock). Joint
Nature Conservation Committee, Peterborough.
MacEwen, E. A. T. & Hobson, A. D. (1954). Occurrence of Paracentrotus lividus (Lamarck)
in Scotland. Nature, London. 174, 752.
McLachlan, J. (1974). Effects of temperature and light on growth and development of
embryos of Fucus edentatus and Fucus distichus ssp distichus. Canadian Journal of
Botany, 52, 943-951.
Maggs, C. A. (1986). Scottish marine macroalgae: a distributional checklist, biogeographical
analysis and literature abstract. Queen's University, Belfast.
Maggs, C. A. and Hommersand, M. H. (1993). Seaweeds of the British Isles. Vol. 1:
Rhodophyta. Pt. 3A Ceramiales. British Museum (Natural History), London.
Manuel, R. L. (1981). British Anthozoa. Synopsis of the British Fauna (New Series), 18.
Marine Biological Association (1957). Plymouth Marine Fauna, 3rd edition. Marine Biological
Association, Plymouth.
McManus, J. F., Bond, G. C., Broecker, W. S., Johnsen, S., Labeyrie, L. & Higgins, S.
(1994). High-resolution climate records from the North-Atlantic during the last
interglacial. Nature, 371, 326-329.
Mitchell, R., Dipper, F.A., Earll, R. & Rowe, S. (1980). A preliminary study of Loch Obisary: a
brackish Hebridean loch. Progress in Underwater Science, New series: 5, 99-118.
Moore, H. B. & Kitching, J. A. (1939). The biology of Chthamalus stellatus Poli. Journal of
the Marine Biological Association of the United Kingdom, 23, 521-541.
36
Moore, P. G. & Seed, R. (eds.) (1985). The Ecology of Rocky Coasts. Hodder & Stoughton,
London.
Mortensen, T. H. (1927). Handbook of the Echinoderms of the British Isles. Oxford University
Press.
Norton, T. A. (1985). Provisional atlas of the marine algae of Britain and Ireland. British
Phycological Society and Nature Conservancy Council, Peterborough.
O'Riordan, R. M., Myers, A. A. & Cross, T. F. (1995). The reproductive cycles of Chthamalus
stellatus (Poli) and C. montagui Southward in south-western Ireland. Journal of
Experimental Marine Biology and Ecology, 190, 17-38.
Pannacciulli, F. G. (1995). Population ecology and genetics of European species of intertidal
barnacles. Phd Thesis, Liverpool University.
Patel, B. & Crisp, D. J. (1960). The influence of temperature on the breeding and the
moulting activities of some warm-water species of operculate barnacles. Journal of
the Marine Biological Association of the United Kingdom, 39, 667-680.
Pearson, G. A. & Brawley, S. H., (1996). Reproductive ecology of Fucus distichus
(Phaeophyceae): an intertidal alga with successful external fertilization. Marine
Ecology Progress Series, 143, 211-223.
Pearson, T.H. & Eleftheriou, A. (1981). The benthic ecology of Sullom Voe. Proceedings of
the Royal Society of Edinburgh, 80B, 241-269.
Picton, B. E. and Costello, M. J. (1998). The BioMar biotope viewer: a guide to marine
habitats, fauna and flora in Britain and Ireland. Environmental Sciences Unit, Trinity
College, Dublin. (CD-ROM.)
Pike, R. B. & Williamson, D. I. (1959). Observations on the distribution and breeding of
British hermit crab and the stone crab (Crustacea: Diogenidae, Paguridae and
Lithodidae). Proceedings of the Zoological Society of London, 132, 551-573.
Powell, H. T. (1957). Studies in the genus Fucus. Journal of the Marine Biological
Association on the United Kingdom, 36, 407-432.
Powell, H. T., Holme, N. A., Knight, S. J. T., Harvey, R., Bishop, G. & Bartrop, J. (1979).
Report on the shores of the Outer Hebrides. In Survey of the littoral zone of the
coast of Great Britain. Nature Conservancy Council, Peterborough.
Powell, H. T., Holme, N. A., Knight, S. J. T., Harvey, R., Bishop, G. & Bartrop, J. (1980a).
Report on the shores of North West Scotland. In Survey of the littoral zone of the
coast of Great Britain. Nature Conservancy Council, Peterborough.
Powell, H. T., Holme, N. A., Knight, S. J. T., Harvey, R., Bishop, G. & Bartrop, J. (1980b).
Report on the shores of the Moray Firth. In Survey of the littoral zone of the coast of
Great Britain. Nature Conservancy Council, Peterborough.
Price, J. H., Tittley, I. & Richardson, W. D. (1979). The distribution of Padina pavonica (L.)
Lamour. (Phaeophyta, Dictyotales) on British and adjacent European shores. Bulletin
of the British Museum of Natural History, 7, 1-67.
Raffaelli, D. & Hawkins, S. J. (1996). Intertidal Ecology. Kluwer Academic, Dordrecht.
Ruddiman, W. F. & McIntyre, A. (1976). Northeast Atlantic paleoclimatic changes over the
past 600,000 years. Geological Society of America Memoir, 45, 111-146.
Russell, F. S. (1935). On the value of certain plankton animals as indicators of water
movements in the English Channel and North Sea. Journal of the Marine Biological
Association of the United Kingdom, 20, 309-332.
37
Russell, F. S. (1973). A summary of the observations on the occurrence of planktonic stages
of fish off Plymouth 1924-1972. Journal of the Marine Biological Association of the
United Kingdom, 53, 347-355.
Sagarin, R. D., Barry, J. P., Gilman, S. E. Baxter, C. H. (1999). Climate-related change in an
intertidal community over short and long time scales. Ecological Monographs, 69,
465-490.
Scott, G. W. & Tittley, I. (1998). Changes in the marine flora of the North Sea. CERCI,
Scarborough.
Seaward, D. R. (1982). Sea area atlas of the marine molluscs of Britain and Ireland. Nature
Conservancy Council, Peterborough.
Seaward, D. R. (1990). Distribution of the marine molluscs of north west Europe. Nature
Conservancy Council, Peterborough.
Seaward, D. R. (1993). Additions and amendments to the distribution of the marine molluscs
of north west Europe (1990). Joint Nature Conservation Committee, Peterborough.
Sideman, E. J. & Mathieson, A. C. (1983). The growth, reproductive phenology, and
longevity of non-tidal-pool Fucus distichus (L.) Powell in New England. Journal of
Experimental Marine Biology and Ecology, 68, 111-127.
Simpson, J.H., Edelsten, D.J., Edwards, A., Morris, N.C.G. & Tett, P.B. (1979). The Islay
front: physical structures and phytoplankton distribution. Estuarine & Coastal Marine
Science, 9, 713-726.
Sole Cava, A. M., Thorpe, J. P. & Todd, C. A. (1994). High genetic similarity between
geographically distant populations in a sea-anemone with low dispersal capabilities.
Journal of the Marine Biological Association of the United Kingdom, 74, 895-902.
South, G. R. & Tittley, I. (1986). A checklist and distributional index of the benthic marine
algae of the North Atlantic Ocean. Huntsman Marine Laboratory and British Museum
(Natural History), St Andrews and London.
Southward, A. J. (1963). The distribution of some plankton animals in the English Channel
and approaches. III. Theories about long-term biological changes including fish.
Journal of the Marine Biological Association of the United Kingdom, 43, 1-29.
Southward, A. J. (1980). The western English Channel an inconstant ecosystem? Nature,
London, 285, 361-366.
Southward, A. J. & Boalch, G. T. (1994). The effect of changing climate on marine life: past
events and future predictions. Exeter Maritime Studies, 9, 101-143.
Southward, A. J., Butler, E. I. & Pennycuick, L. (1975). Recent cyclic changes in climate and
in abundance of marine life. Nature, 253, 714-717.
Southward, A. J. & Crisp, D. J. (1954). The distribution of certain intertidal animals around
the Irish coast. Proceedings of the Royal Irish Academy, 57B, 1-29.
Southward, A. J., Hawkins, S. J. & Burrows, M. T. (1995). 70 years observations of changes
in distribution and abundance of zooplankton and intertidal organisms in the Western
English-Channel in relation to rising sea temperature. Journal of Thermal Biology, 20,
127-155.
Southward, A. J. & Southward, E. C. (1988). Disappearance of the warm-water hermit crab
Clibanarius erythropus from south-west Britain. Journal of the Marine Biological
Association on the United Kingdom, 68, 409-412.
Southward, E.C. & Southward, A.J. (1991). Virus-like particles in bacteria symbiotic in
bivalve gills. Journal of the Marine Biological Association of the United Kingdom, 71,
37-45.
38
Southward, A. J. & Southward, E. C. (1992). Distribution of Pogonophora (tube-worms) in
British Columbian fjords. Marine Ecology Progress Series, 82, 227-233.
Spirlet, C., Grosjean, P. & Jangoux, M. (1998). Reproductive cycle of the echinoid
Paracentrotus lividus: analysis by means of the maturity index. Invertebrate
Reproduction and Development, 34, 69-81.
Tebble, N. (1966). British Bivalve Seashells. The British Museum (Natural History), London.
Turrell, W.R. (1999). Scottish Ocean Climate Status report 1998. Fisheries Research
services Report No. 9/99.
Todd, C. D. & Lewis, J. R. (1984). Effects of low air temperature on Laminaria digitata in
south-western Scotland. Marine Ecology Progress Series, 16, 199-201.
Whitehead, P. J. P., Bauchot, M.-L., Hureau, J.-C., Nielsen, J. & Tortonese, E. (1986).
Fishes of the North-eastern Atlantic and the Mediterranean. UNESCO, Paris.
Wilkie, I. C. (1989). The fauna of the Clyde Sea area. Echinodermata. Scottish Marine
Biological Association Occasional Publication No. 6, 62p.
Wilkinson, M., Scanlan, C. M. & Tittley, I. (1988). The attached flora of the estuary and Firth
of Forth, Scotland. Proceedings of the Royal Society of Edinburgh, 93, 343-354.
Wilkinson, M. & Tittley, I., (1979). The marine algae of Elie, Scotland: a reassessment.
Botanica Marina, 22, 249-256.
Wilkinson, M., Tittley, I., Scanlan, C. & Wells, E. (2000) (in press). Biodiversity of intertidal
seaweeds II. Reassessment of shores on Orkney 25 years after the British
Phycological Society Field Meeting. The Phycologist.
Wilson, D. P. (1951). A biological difference between natural sea waters. Journal of the
Marine Biological Association of the United Kingdom, 30, 1-19.
Wilson, D. P. (1977). The stability during many years of the mid-tidal shore at Penrhyn Bay,
North Wales, and a note on the peat beds at Rhos-on-Sea. Estuarine and Coastal
Marine Science, 5, 209-213.
Wood, R. A., Keen, A. B., Mitchell, J. F. B. & Gregory, J. M. (1999). Changing spatial
structure of the thermohaline circulation in response to atmospheric CO2 forcing in a
climate model. Nature, 399, 572-575.
Woodward, F. R. (1985). The fan-mussel, Pinna fragilis Pennant, in Scotland. Glasgow
Naturalist, 21, 63-69.
39
40
APPENDICES
Appendix 1. Information on species distributions from A.J. Southward and S.J.
Hawkins
Polychaetes
Anecdotal evidence (I. Rees, pers. comm. to S.J. Hawkins; S.J. Hawkins, own observations)
suggest that Sabellaria which was trimmed back from Llandudno/Penrhyn (Wilson, 1977) to
Criccieth following the cold winter of 1962/3 has been very slow to recover in this area
(Cunningham et al., 1984).
Sea urchins
Mention has been made of the southern or lusitanian sea urchin Paracentrotus lividus.
Forbes recorded this from Donegal Bay to the south-west tip of Cork. The Crisp and
Southward data for 1958 show it as extending from just east of Malin Head in north Donegal
to the western side of the Old Head of Kinsale. Towards each of these limits there is a
dramatic drop in intertidal abundance, suggesting some strong environmental character is
affecting settlement and survival rather than availability of planktonic larvae. In Brittany the
species was heavily fished after the baseline survey of Fischer Piette (1933, 1937), and by
the 1970s it could be found only with difficulty at the most inaccessible headlands. A similar
trend began to develop in south-west Ireland with the rise of commercial fishing, but
Paracentrotus was still abundant in Galway Bay in the 1970s. Records of this sea-urchin to
the north and east of Brittany and Ireland are very few. Several finds of Paracentrotus are
listed in the Plymouth Marine Fauna (Marine Biological Association, 1957). The first record
of Paracentrotus from Scottish waters was by Hobson in 1950 (MacEwen & Hobson, 1954),
for a specimen collected on Muck. Later, specimens were found in the Sound of Sleat. A
survey of Skye by Southward and Southward in 1971 found it at the Point of Sleat (2
specimens) and at Duntulm Castle (one specimen). With global warming, and if fishing is
prevented, this sea-urchin is very likely to become more common in western Scotland,
particularly in the area from Tiree to Skye, where sea surface temperature may be higher
than farther north. However, it was not found by detailed searching on Tiree in 1962. More
recently P. lividus was recorded during 1999 in Eigg (J. M. Baxter and D. Donnan, pers.
comm.) and Barra (S. Scott, pers. comm.). If it became very abundant this species might
have ecological consequences for the fauna and flora due to intense grazing pressure, as
reported in other regions where related genera can be locally abundant.
The arctic/boreal sea urchin, Strongylocentrotus droebachiensis, which to some extent
occupies a similar but deeper water (in Shetland) habitat to Paracentrotus, is smaller and
less obvious. It is abundant at times in Shetland (see photograph in Baxter & Usher 1994),
and has been reported from the sublittoral of the North Sea coasts of Scotland. It occurs in
Norway, off eastern Canada and in Alaska. This species would be expected to decline in
Scotland in the face of global warming, but this would probably not affect otters that might
feed on it along the coast, since Echinus esculentus would still be available for them.
Seastars
The common seastar, Asterias rubens is present on most suitable shores in Britain under
stones at LW, and also sublittorally, ranging down to 100m. In west coast Scottish localities
it is accompanied by, or may be replaced by, the boreal starfish Leptasterias muelleri, which
differs in incubating it eggs rather than producing pelagic larvae. The Crisp and Southward
data suggests that Leptasterias is best developed inside the sea lochs; there are records
from Loch Melfort in Argyll, and from Loch Eport, Loch Roag and Bernera Sound in the outer
islands. This species would be expected to be a sensitive indicator of global climate change,
but requires careful searching and good identification skills.
Molluscs
Certain bivalve molluscs that live in sulphide-rich habitats include species that are of
arctic/boreal distribution, belonging to Forbes’ group of ‘boreal outliers’. The genus Thyasira
contains a number of cold water species recorded from west coast Scottish sea lochs,
41
notably Thyasira gouldii, and Thyasira ferruginea (Forbes & Hanley, 1853). Thyasira
ferruginea was reported from the upper Clyde Sea and Loch Fyne, areas where other coldwater species occur (for example, Calanus finmarchicus and Meganyctiphanes norvegica
are abundant in the plankton of Loch Fyne and Loch Striven). But extensive dredging in
Loch Fyne and off Millport in 1984 produced only the warm-water species Thyasira flexuosa.
And specimens in the faunal collection at the Millport Marine Station, labelled “Thyasira
ferruginea”, were also the warm water species. In contrast, the occurrence in Scottish
waters of Thyasira gouldi, was confirmed by Blacknell & Ansell (1974), who found it
abundant in Loch Etive in the 1970s. By 1989 this population had so declined that only two
live specimens were taken in several days bottom sampling (Southward & Southward, 1991,
1992). It is not clear if this decline was a result of climate changes or local factors such as
change in land use and in run-off from the land. Unfortunately there has been no recent
funding available for re-investigation of the benthos in other Scottish lochs.
The top-shell Osilinus (=Monodonta) lineata has been found from Roman villas on the Isle of
Wight and in large quantities in middens on Portland. In recent times its eastern limit in the
English Channel has been Lyme Regis (in numbers) although odd specimens have been
found on Portland. Recent warming along the South coast has not seen much increase in
abundance or range on a time scale of decades (S.J. Hawkins, pers. observs. 1980-2000 –
Lyme Regis to the Isle of Wight). Similarly, in North Wales, Osilinus lineata were trimmed
back from Anglesey to Criccieth following the cold winter of 1962/3, with only odd specimens
being found at Rhosneigr and other locations by S.J. Hawkins and research students in the
mid 1980s and early 1990s.
In the early 1980s a broad scale survey of the proportions of the limpets Patella depressa to
Patella vulgata was undertaken (Hawkins, unpublished, some data are in Southward et al.,
1995). This showed lower abundance of the southern species, Patella depressa at most
sites from Anglesey to the Isle of Wight on the south and west coasts, and also in northern
France compared to surveys by Crisp & Southward (1958), Crisp & Fischer-Piette (1959)
and unpublished records of Southward & Crisp. No changes in range were detected but
abundance at the extreme limits of Patella depressa was much reduced. Observations in
Portugal also suggested that Patella vulgata was spreading southwards, a trend first spotted
by Fischer-Piette in the 1960s. Patella depressa has recovered to some extent in the late
1980s to 1990s (Southward et al., 1995; S.J. Hawkins pers. observs.) so this species
appears to have responded rapidly to warming.
Crustacea
In addition to the barnacles commented upon in the main text, a number of crustaceans
have been shown to have distribution limits in the British Isles. In particular, the small hermit
crab, Clibanarius erythropus colonized south-west England in the 1950s, but disappeared
during the cold spell after 1962 (Southward & Southward, 1988). Another hermit crab of
southern character, Catapagurus timidus, which occurs from the Mediterranean to Brittany,
was recorded from the Isles of Scilly and south-west Scotland during the 1950s (Harvey
1964; Pike & Williamson 1959). These two southern species might well flourish in Scottish
waters if warming continues.
The large spider crab, Maja squinado, is common in south-west Britain (Marine Biological
Association, 1957). It is occasionally taken in the Irish Sea (Bruce et al., 1963). The stone
crab, Lithodes maia, is a northern form of similar habitat that reaches its southern limits in
the Celtic Sea (personal record) and is sometimes encountered in the Irish Sea (Bruce et al.,
1963). These two species might be expected to change their distribution and abundances
with rising temperatures, one advancing, the other retreating north.
Pogonophoran tube-worms
The small perviate Pogonophora are mostly found in the deep sea, but a few species extend
up onto the continental shelves where the water is stratified in summer, where the
temperature on the bottom is below 10°C in summer, and where autumn mixing does not
42
increase sea temperature above 13°C. An outlying population of one pogonophoran,
Siboglinum holmei, was recorded in the North Minch in 1963, and another population off
Kerry was sampled in 1957 and 1960 (Southward, 1963). This species has not been
reported from the west coast sea lochs, in contrast to conditions in Norway where a
comparable species extends close inshore in the fjords around Bergen. The Minch
population would be at risk only if sea temperatures were to increase by several degrees.
Fish
It needs to be remembered that herring are at their southern limit in the British Isles and
Brittany. This northern fish would be at risk from rising temperatures. The Clyde herring
stock might be affected by warming in the same way as the Plymouth stock in the 1930s,
when recruitment failed under increasing temperatures, competition with pilchard, and overfishing.
In contrast, pilchard might extend their range northwards with rising sea temperatures. The
breeding range of pilchard during the warm phase before 1962 extended from W. Ireland to
the southern North Sea, including most of the English Channel. The breeding range was
more restricted in the cold spell from 1963 to 1980, but extensive spawning returned to
Plymouth waters after 1981.
Algae
A number of species of macroalgae of southern character penetrate into Scottish waters,
notably Cystoseira tamariscifolia in the inner and outer Hebrides (no records for Harris and
Lewis though). Another southern species, Bifurcaria bifurcata, is much more widespread on
the western coast of Ireland than shown in the Provisional Atlas of Marine Algae (Norton
1985), extending from south-west Cork to west Donegal (54° N). It was not seen in Scotland
by Crisp and Southward in 1953-62, and there are no Scottish Records in the Provisional
Atlas (Norton, 1985). However, more interest attaches to those algae of northern character,
already close to their southern limit in the British Isles. Powell (1957) charted the distribution
of Fucus distichus distichus down the western coasts, and the Crisp & Southward database
includes records for 1958 in Kerry and Clare, 1962 in Barra and 1953 in Orkney; there are
records for St. Kilda but not for the inner Hebrides (Norton, 1985). There are no additional
records of this northern fucoid for the cool period of 1962-1980 when the species might
possibly have been expected to increase its range. It has never been recorded from the
east coast of Scotland. F. distichus distichus is likely to retreat northwards under the
influence of global warming, but debilitating effects of higher temperatures might be
mitigated if the weather became more stormy and exposed rocks more frequently washed by
waves. The red alga Odonthalia dentata reaches its southern limits in the Irish Sea and may
retreat northwards.
Ascophyllum nodosum is a boreal species that reaches its southern limit in the British Isles
and Northern France. It is a characteristic dominant of the mid-intertidal of sheltered
Scottish shores, and was formerly exploited for agriculture and industry (fertilizer, iodine,
alginates). It is still grazed by sheep at some localities. In the south of England there are
signs that this alga is under stress and may not be recruiting. At a shore near Plymouth the
well-documented decline of this species between the 1930s and the 1970s has been
attributed to anthropogenic factors (Holme and co-workers in the1970s), but it is likely that
climate effects may also be involved. Across the Channel, the species flourishes in Brittany
and survives harvesting. However, along the north coast of Brittany the strong tidal mixing
provides lower summer sea temperatures, and also increases the supply of inorganic
nutrients.
43
44
Appendix 2. Benthic marine species which occur in Scotland or may spread there or
be affected by expected climate change and which are listed in statutes, directives or
Biodiversity Action Plans.
UK BAP = UK Biodiversity Action Plan. W&C Act = Wildlife & Countryside Act 1981. NI
Order = Wildlife (NI) Order 1985.
* = species for which basic information on current distribution and biology relevant to climate
change effects has been undertaken (Appendix 5). ** = species for which information on
current distribution and biology relevant to climate change effects has been researched and
predictions made of future likley change in distributions and abundance (Appendix 7).
Species
Common
name
Statute,
directive
or BAP
UK BAP
W&C Act
Sched. 5
Species
statement
in UK
BAP
Found in
Distribution
Scotland
No
Records from the south west of
England and Wales and the west
coast of Ireland only.
Yes
Numerous records for the west of
Scotland.
Eunicella
verrucosa**
pink sea-fan
Funiculina
quadrangularis *
tall sea pen
Amphianthus dohrnii
*
sea fan
anemone
UK BAP
Yes
Sabellaria alveolata *
Honeycomb
worm
UK BAP
Yes
Sabellaria spinulosa
ross worm
UK BAP
Yes
Modiolus modiolus*
horse mussel
UK BAP
Yes
Atrina fragilis *
a fan shell
UK BAP
Yes
Ostrea edulis *
native oyster
UK BAP
Yes
Thyasira gouldi *
northern
hatchett shell
UK BAP
Yes
45
Recorded off Mull and Jura and in
the Firth of Lorn. Also present off
the south coast of Devon and
Cornwall and at Lundy.
Predominantly southern in
occurrence. Recorded in the
Solway Firth in Scotland as well as
other locations on the west of the
UK. One record from Lewis.
Recorded thoughout the UK but
reefs or crusts recorded only in
southern Scotland.
Recorded thoughout the UK
although only occurs as beds of
large individuals north of west
Wales. Important in forming five
biotopes in Scotland.
Recorded off the west of Scotland
(especially around Mull), Shetland,
Orkney and the Moray Firth. Also
present in south-west England.
Rarely encountered.
Recorded off the west coast of
Scotland and Shetland.
Northern species recorded from
upper Loch Etive, Loch Eil and
Loch Sunart. The status at the
latter two sites is currently
unknown.
Echinus esculentus
edible sea
urchin
Styela gelatinosa *
a sea squirt
Pomatoschistus
microps
common goby
Pomatoschistus
minutus
sand goby
Lithothamnion
corallioides *
Phymatolithon
calcareum
Anotrichium
barbatum
Ascophyllum
nodosum ecad
mackaii *
Zostera marina /
angustifolia
IUCN
Red Data
Book;
NI Order
Shed.7
Species
statement
in UK
BAP
Berne
Conv.
App. III
Berne
Conv.
App. III
Yes
Recorded thoughout the UK.
Yes
Records from Clyde sea only.
Yes
Recorded commonly around
Scotland and off the south coast of
England.
Yes
Recorded thoughout the UK.
Recorded off the west coast of
Scotland and Shetland. Also
occurs of the west coast of Ireland
and SW England.
Commonly recorded in Scotland,
also occurs on the west coast of
the England and Wales.
Maerl
Habitats
Directive
Annex V
Yes
Maerl
Habitats
Directive
Annex V
Yes
a red alga
UK BAP
No
Recorded in Cardigan Bay only
a brown alga
UK BAP
Yes
Recorded off Lewis, Shetland and
the west coast of Scotland.
eel grass
UK BAP
Yes
Commonly recorded in Scotland,
also occurs on the west coast of
the UK.
46
Appendix 3. Benthic biotopes which are part of Biodiversity Action Plans (BAPs) and
are either found in Scotland or are likely to spread there in response to expected
climate change.
* = included in detailed reviews of likely effects of climate change (Appendix 7). Habitat
Directive Annex 1 habitats are: S = Sandbanks which are slightly covered by seawater all
the time; E = Estuaries; M&S = Mudflats and sandflats not covered by seawater at low tide; L
= lagoons; B = Large shallow inlets and bays; R = Reefs; C = Caves.
Intertidal and
subtidal
habitats
Sabellaria
alveolata
reefs
Mudflats
Sheltered
muddy
gravels
Sabellaria
spinulosa
reefs
Tidal rapids
Biotope code
Main Species
Notes
Recorded from south and
west coasts of England
Sabellaria
MLR.Sab.Salv *
and Wales and as far
alveolata
north as the Solway Firth.
One record from Lewis.
Contains 4 distinct
biotopes which occur in
Scotland yet are not
LMU.Smu
special or likely to be
affected by climate
change.
Contains 3 distinct
LMU.Mu
biotopes that just extend
into Scotland.
Contains 4 distinct
biotopes which occur in
Scotland yet are not
LMS.MS
special or likely to be
affected by climate
change.
Venerupis
Not special to Scotland or
IMX.FaMx.VsenMtru senegalensis & likely to be affected by
Mya truncata
climate change.
Not special to Scotland or
Mya arenaria &
LMX.Mare
likely to be affected by
polychaetes
climate change.
Mytilus edulis & Not special to Scotland or
LMX.MytFab
Fabricia
likely to be affected by
sabella
climate change.
burrowing
IMX.FaMx.An
No records.
anemones
Reefs (including crusts)
recorded off the coasts of
Sabellaria
CMX.SspiMx *
spinulosa &
England and Wales, just
Polydora spp.
extending north into
Scotland.
Contains 4 distinct
biotopes which occur in
Scotland but are not
ECR.Alc
special to Scotland or
likely to be affected by
climate change.
47
Habitats
directive
habitat
R
M&S
L
M&S
M&S
L
E
B
E
B
E
B
N/a
R
R
B
ECR.BS
Contains five distinct
biotopes which occur in
Scotland. All except
ECR.HbowEud (see
below) are not special to
Scotland or likely to be
affected by climate
change.
R
B
Halichondria
bowerbanki,
Eudendrium
ECR.BS.HbowEud *
arbusculum &
Eucratea
loricata
Recorded from the Clyde
area sea lochs only.
R
B
Recorded off the
Shetland, Orkney, west
Scotland, Wales and east
England.
R
B
Recorded in Strangford
Lough only.
R
B
Recorded off west
Scotland, Shetland and
Orkney only.
R
B
Recorded off west
Scotland, Shetland,
Orkney and NW Wales.
R
B
Recorded off west
Scotland and Shetland.
R
B
Tidal rapids
CMX.ModMx *
Modiolus
modiolus
Modiolus
modiolus &
Chlamys varia
Modiolus
Modiolus
SCR.Mod.ModHAs * modiolus & fine
modiolus beds
hydroids
Modiolus
modiolus &
MCR.M.ModT *
hydroids & red
algae
Cerianthus
lloydii &
CMX.ModHo *
Modiolus
modiolus
Zostera marina
IMS.Sgr.Zmar
& Z.
angustifolia
SCR.Mod.ModCvar
*
Seagrass
beds
IMS.Sgr.Rup *
Ruppia
maritima
LMS.Zos.Znol
Zostera noltii
IMX.MrlMx.Lden
IMX.MrlMx.Lfas
Maerl beds
IMX.MrlMx.Lcor *
Lithothamnion
dentatum
Lithothamnion
fasciculatum &
Chlamys varia
Lithothamnion
corallioides
48
Not special to Scotland or
likely to be affected by
climate change.
Recorded off west
Scotland (especially the
Outer Hebrides),
Shetland, Orkney and the
Moray Firth.
Not special to Scotland or
likely to be affected by
climate change.
Knowledge of distribution
is incomplete.
S
L
S
L
S
M&S
S
B
Occurs in SW Ireland.
S
B
Recorded in SW Ireland
and UK. Scottish records
are unconfirmed due to
problems with
identification.
S
B
IGS.Mrl.Lgla *
Lithothamnion
glaciale
IGS.Mrl.Phy *
Phymatolithon
calcareum
IGS.Mrl.Phy.Hec
Phymatolithon
calcareum,
hydroids &
echinoderms
IGS.Mrl.Phy.R
Phymatolithon
calcareum &
red algae
IMU.Ang.NVC A12
Potamogeton
pectinatus
IMU.Ang.NVC S4
Phragmites
australis
CMU.SpMeg
Seapens &
burrowing
megafauna
CMU.SpMeg.Fun *
Seapens &
Funiculina
quadrangularis
CMU.Beg *
Beggiatoa spp.
CMU.BriAchi
Brissopsis
lyrifera &
Amphiura
chiajei
COS.ForTHy
Foramaniferans &
Thyasira sp.
COS.Sty *
Styela
gelatinosa
Maerl beds
Saline
lagoons
Mud habitats
in deep water
49
Northern species with
southern recorded limit at
Lundy. Recorded in west
Scotland and Shetland.
Found in variable salinity
habitats.
Recorded off NW
Scotland and Orkney.
The major maerl bed
biotope in Scotland.
Recorded off west
Scotland, Shetland,
Orkney, Strangford
Lough and from
Plymouth.
Recorded off west
Scotland, Shetland,
Orkney, Pembrokeshire
and from Plymouth.
Recorded on Barra, in
Shetland and Orkney.
Occurrence is according
to presence of lagoon
conditions rather than
temperature.
Recorded in the Harris
area only in the UK.
Occurrence is according
to presence of lagoon
conditions rather than
temperature.
Recorded extensively in
Scottish west coast sea
lochs, Western Isles and
Shetland. Also occurs in
the Irish Sea, North Sea
and off the south coast of
England.
Recorded in Scottish
west coast sea lochs.
Recorded in Scottish
west coast sea lochs.
Recorded in the northern
Irish Sea, Clyde, Minch
and some Scottish sea
lochs (e.g. Loch Etive).
Recorded in the northern
North Sea, some west
coast Scottish sea lochs
(Lochs Eil & Nevis) and
the southern Irish Sea.
Recorded in Clyde sea
loch only (Loch Goil).
S
B
S
B
S
B
S
B
L
L
B
B
B
B
B
B
Serpulid reefs
CMS.Ser *
IGS.FaG.HalEdw *
Sublittoral
sands and
gravels
IGS.FaG.Sell
IGS.FaS.NcirBat
Reefs only recorded from
Loch Creran and Loch
Serpula
Sween on west coast of
vermicularis
Scotland. Reefs in the
latter are now reported to
be dead.
Recorded in west
Scotland in Loch Creran,
Halcampa
chrysanthellum Loch Eynort (Skye) and
Church Bay (Rathlin
& Edwardsia
Island). Also occurs in
timida
Strangford Narrows.
A common habitat with
Spisula elliptica
examples found from
& venerid
Shetland to the Isles of
bivalves
Scilly.
Nephyts cirrosa Commonly recorded in
& Bathyporeia full salinity areas of many
spp.
estuaries.
50
B
R
S
B
S
B
S
B
Appendix 4. Species with climatically restricted distributions or abundance in or near
Scotland
* = species for which basic information on current distribution and biology relevant to climate
change effects has been undertaken (Appendix 5). ** = species for which information on
current distribution and biology relevant to climate change effects has been researched and
predictions made of future likley change in distributions and abundance (Appendix 7).
Species
Common name
Current distribution other comments
North or
South
Porifera
Axinella dissimilis*
A branching
sponge
Ciocalypta penicillus*
A sponge
Hemimycale columella
A sponge
Phorbas fictitius
A sponge
Haliclona angulata
A sponge
Haliclona cinerea
A sponge
Haliclona fistulosa
A sponge
Haliclona simulans
A sponge
Recorded in the British Isles as far north
as Mull, Northern Ireland and Anglesey.
Recorded in the British Isles as far north
as Northern Ireland and Anglesey.
Recorded off west Scotland and Shetland
in Scotland.
Records from west Scotland, Orkney and
Shetland in Scotland.
Only recorded from SW Britain in the
British Isles.
Recorded from west Scotland and Orkney
in Scotland.
Recorded from west Scotland and Orkney
in Scotland.
A southern species with a few records
from west Scotland and Orkney.
S
S
S
S
S
S
S
S
Cnidaria
Thuiaria thuja*
Bottle-brush
hydroid
Gymnangium
montagui*
Yellow feathers
hydroid
Alcyonium
glomeratum*
Red sea fingers
Swiftia pallida**
Northern sea-fan
Eunicella verrucosa**
A sea-fan
Funiculina
quadrangularis*
Tall sea pen
Anemonia viridis**
Snakelocks
anemone
A northern species recorded south to off
Northumberland in the British Isles
Records from the Firth of Forth, Orkney,
Shetland and Lewis in Scotland.
A southern species extending as far north
as Northern Ireland and Anglesey in the
British Isles.
A southern species with scattered records
from the west coast of Scotland.
Only recorded in west Scotland and St
Kilda in the British Isles.
A southern species recorded as far north
as north-west Ireland and south-west
Wales in the British Isles.
Recorded on the north and west coasts of
Ireland and Scotland. Also occurs in the
Mediterranean. Species statement in UK
BAP. Geographical distribution does not
indicate likleyhood of significant climate
change effects.
Widely recorded on the west coast of
Britain and Orkney but not recorded in
Shetland during extensive surveys.
51
N
S
S
N
S
S
Bolocera tuediae*
Aulactinia
(=Bunodactis)
verrucosa*
An anemone
Gem anemone
Aiptasia mutabilis
Trumpet
anemone
Phellia gausapata**
An anemone
Amphianthus dohrnii*
Sea fan
anemone
Corynactis viridis*
Jewel anemone
The only records in Britain are off the
south-east coast of Scotland and north
east cost of England and south-west
coasts of Scotland.
A southern species recorded at a few
locations in south-west Scotland and
Shetland.
A southern species recorded as far north
as Anglesey in the British Isles.
A northern species recorded in west
Scotland, Shetland and Northern Ireland
in the British Isles.
Recorded in west Scotland and a few
locations in south-west Britain. UK BAP
species. Geographical distribution does
not indicate likleyhood of significant
climate change effects unless the host in
Scotland (Swiftia pallida) declines without
replacement by a southern host
(Eunicella verrucosa).
A southern species. Recorded on open
wave exposed coasts in western
Scotland, Orkney and Shetland in
Scotland.
N
S
S
N
S
Annelida
Sabellaria alveolata*
Honeycomb
worm
A southern species. The only Scottish
records are from the Solway Firth and on
Lewis.
S
Crustacea
Chthamalus
montagui**
Montagu’s
punctate
barnacle
Chthamalus stellatus**
Poli’s stellate
barnacle
Balanus perforatus
A barnacle
Hippolyte huntii
A shrimp
Palinurus elephas*
Crawfish
Lithodes maia**
Polybius henslowi
Northern stone
crab
Henslow’s
swimming crab
Southern species commonly recorded off
the north and west coasts of Scotland,
present in Orkney and Shetland. Also
rare at a few places on the east coast.
A southern species recorded off west
Scotland, Shetland and Orkney in
Scotland.
Only recorded in south-west Britain as far
north as south Wales in the British Isles.
A southern species which has been
recorded off west and south east Ireland
and south west England in the British
Isles but is rare. Recorded in Scotland
also recorded at Strome Narrows.
Previously widely distributed in southwest Britain in the British Isles but has
declined in the past 20 years. Recorded
on the west coast of Scotland, Orkney
and Shetland. Also a few records from
the east coast of Scotland.
A northern species recorded in west
Scotland and Shetland in the British Isles.
Southern species recorded throughout
Britain except in Shetland.
52
S
S
S
S
S
N
S
A southern species recorded at a few
locations in south-west Scotland in
Scotland.
A southern species that only extends as
Thorn backspider
Maja squinado **
far north as the Isle of Man and northcrab
west Ireland in the British Isles.
A southern species recorded on southCorystes
west coast of Scotland and in Orkney in
Maskeed crab
cassivelaunus
Scotland.
Arch-fronted
A southern species recorded at a few
Liocarcinus arcuatus
swimming crab
locations in the south-west in Scotland.
A southern species recorded from west
Wrinkled
Liocarcinus corrugatus
Scotland and Lewis in Scotland. Also
swimming crab
common in Orkney.
A southern species recorded from a few
Goneplax rhomboides* Angular crab
locations on the west coast of Scotland.
A southern species recorded on the west
Pilumnus hirtellus
Bristly crab
coast of Scotland and in Orkney.
A southern species recorded on the
Xantho incisus*
Montagu's crab
south-west coast of Scotland.
A southern species recorded on the west
Xantho pilipes
A crab
coast of Scotland and in Shetland
Mollusca
Northern species recorded as far south as
Tonicella marmorea
A chiton
Northumberland and North Wales.
A southern species of snail recorded off
Tricolia pullus
Pheasant shell
the west coast of Scotland but not in
Orkney or Shetland.
A northern species recorded in both west
Margarites helicinus*
Pearly top shell
and east Scotland, Shetland and Orkney.
A southern species commonly recorded
on the west coast of Britain and present in
Gibbula umbilicalis**
Flat top shell
Orkney.
A southern species which reaches its
Osilinus lineatus
Toothed top shell northern limits in Northern Ireland and
(=Monodonta lineata)**
Anglesey in the British Isles.
A northern species commonly recorded
Tortoiseshell
throughout Scotland but reaching its
Tectura testudinalis**
limpet
southern limit in the Irish Sea in the
British Isles.
A southern species which reaches its
Black-footed
Patella depressa**
northern limits at Anglesey in the British
limpet
Isles.
Commonly recorded on the west coast of
Britain and present in Orkney. Also
Patella
ulyssiponensis** (=
A limpet
occurs in Shetland and on the east coast
Patella aspersa)
of Britain as far south as Filey in
Yorkshire.
Recorded off west Scotland and Orkney
Bittium reticulatum
Needle whelk
in Scotland.
Cerithiopsis
Occasionally recorded off west Scotland.
A gastropod
tubercularis
Ebalia tumefacta
Bryer's nut crab
53
S
S
S
S
S
S
S
S
S
N
S
N
S
S
N
S
S
S
S
Melaraphe neritoides
Small periwinkle
Onoba aculeus
A gastropod
Calyptraea chinensis*
Chinaman's hat
Crepidula fornicata
Slipper limpet
Clathrus clathrus
A gastropod
Ocenebra erinacea
Oyster drill
Colus islandicus
A gastropod
Acteon tornatilis
A gastropod
Akera bullata
A sea slug
Pleurobranchus
membranaceus
A sea slug
Tritonia nilsodhneri
A sea slug
Atrina fragilis*
Fan mussel
Limaria hians
File shell
Ostrea edulis*
Native oyster
Crassostrea virginica
American oyster
Anomia ephippium
Common saddle
oyster
A southern species that occurs on wave
exposed rocky coasts. Commonly
recorded throughout Britain.
A northern species recorded off east and
west Scotland, Orkney and Shetland
Rarely recorded in south-west Scotland
and west Ireland.
An introduced species recorded as far
north as the Wash and south-west Wales
in the British Isles.
Records from Mull and Moray Firth.
Recorded off east Scotland, Shetland and
the Firth of Forth
A northern species with a few British
records from north Scotland, Shetland
and Northern Ireland.
Occasionally recorded all around Scottish
mainland.
Northern species recorded off west
Scotland, Shetland, Orkney and Moray
Firth.
Recorded off west Scotland, Orkney and
Shetland.
This species has a south-western
distribution in the British Isles and is
recorded as far north as NW Ireland.
Present in south west England and
western Scotland in the British Isles.
Recorded off the west of Scotland
(especially around Mull), Shetland,
Orkney and the Moray Firth. Rarely
encountered.
A northern species recorded often in large
numbers in west Scotland But also
recorded on the south coast of England in
the British Isles.
Recorded from Norway to the
Mediterranean and the Black Sea.
Widely distributed around the British Isles.
UK BAP species. Geographical
distribution does not indicate likleyhood of
significant climate change effects
An introduced species not recorded in
Scotland.
Commonly recorded from north and west
Scotland, Shetland and Orkney. Also
occurs in the Firth of Forth. Included here
because it is an important componant of
biotopes in Scotland.
54
S
N
S
S
S
S
N
S
N
S
S
S
N
S
N
Thyasira gouldi*
Cerastoderma
glaucum
Solen marginatus
Gari depressa*
Northern species recorded from upper
Loch Etive, Loch Eil and Loch Sunart.
Northern hatchett The status at the latter two sites is
shell
currently unknown. These are the most
southerly European populations of this
species.
Rarely recorded on both coasts of
Lagoon cockle
Scotland and Orkney.
Grooved razor
A southern species recorded as far north
shell
as Anglesey.
Large sunset
A southern species, just extending north
shell
into west Scotland in the British Isles.
N
S
S
S
Bryozoa
Pentapora fascialis**
(= Pentapora foliacea)
Ross
A southern species abundant in
southwest Britain and recorded off west
Scotland including at St Kilda.
S
Echinodermata
Leptometra celtica
Asterina gibbosa*
Leptasterias muelleri*
Paracentrotus lividus**
Strongylocentrotus
droebachiensis **
Holothuria forskali**
Cucumaria frondosa**
Only recorded on the west coast of
Scotland in Britain.
Recorded off west Scotland and Orkney
Cushion star
in Scotland.
A northern species recorded south to the
A star fish
Isle of Man and to Durham on the coast of
Britain.
A southern species which is abundant in
parts of south-west Ireland but has only
Purple sea
sporadic recorded occurrences in south
urchin
west England and at a few locations on
the west coast of Scotland.
A northern species confined to Shetland
Green sea urchin
and Orkney in coastal waters.
A southern species that is abundant in
parts of south west England. Recorded
Cotton spinner
off west Ireland and a few locations off
west Scotland around Rum.
A northern species widely recorded in
Northern sea
small numbers in Shetland, also occurs in
cucumber
Orkney.
A crinoid
N
S
N
S
N
S
N
Tunicata
Phallusia mammillata
A sea squirt
Styela gelatinosa*
A sea squirt
A southern species recorded as far north
as Anglesey.
Only British population is in Loch Goil
(Clyde Sea). Also occurs in Scandinavia
and Iceland.
S
N
Pisces
Centrolabrus exoletus
Crenilabrus melops
Ctenolabrus rupestris
Most abundant in southern Britain but
recorded off west Scotland and in Orkney.
Most abundant in southern Britain but
Corkwing wrasse
recorded off west Scotland and Orkney.
Recorded off west Scotland, Shetland
Goldsinny
and Orkney but not in large numbers
wrasse
compared with densities in similar habitas
in Norway.
Rock cook
55
S
S
S
Labrus mixtus*
Cuckoo wrasse
Lumpenus
lumpretaeformis
Snake blenny
Thorogobius
ephippiatus*
Algae
Leopard-spotted
goby
Scinaia furcellata
A red alga
Scinaia trigona (= S.
turgida)
A red alga
Asparagopsis armata
(Falkenbergia phase)
A red alga
Bonnemaisonia
hamifera*
A red alga
Naccaria wiggii
A red alga
Jania rubens*
A red alga
Lithothamnion
corallioides
Maerl
Lithothamnion
glaciale*
Maerl
Widely recorded off north and west
Scotland, Orkney and Shetland but
uncommon. Also occurs in the Firth of
Forth.
Northern species recorded off west
Scotland, Shetland, Orkney only in the
British Isles.
Recorded off west Scotland, Orkney and
in the Firth of Forth.
Present from the Mediterranean and
Morocco to southern Norway. Southern
species recorded as far north as
Anglesey and south-west Ireland. In the
British Isles. Also a single Scottish record
from Barra.
Present from the Mediterranean and
Portugal to the British Isles. Recorded in
west Scotland and Shetland
The tetrasporophyte (Falkenbergia)
phase of Asparagopsis armata) occurs as
far north as Shetland but is not recorded
from the east of Scotland. Not recorded
from Northern Ireland.
(The gametophyte phase is recorded from
a few locations in south-west England
and from southern Ireland in the British
Isles).
The tetrasporophyte phase (Trailliella) is
widely distributed from Mauritania to
northern Norway but the gametophyte
(Bonnemaisonia) phase is only found
between Spain and south-west England.
Present from the Mediteranean and Spain
to southern Britain as far north as the Isle
of Man. There is a single Scottish record
from north-west Scotland that requires
checking.
Southern species occuring as far north as
Norway. In British Isles recorded
northwards to west Inverness and
Aberdeen. Very rare in Northern Ireland.
Present from the Canary Isles to Norway.
Recorded off west Scotland and Shetland
but records need checking and many are
dubious. A southern species.
Present from northern British Isles to
Arctic Russia. A northern species
commonly recorded in west Scotland,
Shetland, Orkney and the Firth of Forth.
Common in Northern Ireland. Recorded
reliably south to Lundy and to
Flamborough on the east coast of
England.
56
S
N
S
S
S
S
S
S
S
N
Mesophyllum
lichenoides*
A calcified red
alga
Phymatolithon
calcareum*
Maerl
Calliblepharis ciliata
A red alga
Chondracanthus
(=Gigartina) acicularis
A red alga
Callophyllis cristata*
A red alga
Kallymenia reniformis
A red alga
Stenogramme
interrupta*
A red alga
Rhodymenia delicatula A red alga
Rhodymenia holmesii*
A red alga
Rhodymenia
pseudopalmata
A red alga
Halurus equisetifolius
A red alga
Sphondylothamnion
multifidum*
A red alga
Drachiella heterocarpa
(=Myriogramme
heterocarpum)
A red alga
Drachiella spectabilis
A red alga
Present from Mauritania north to the
British Isles. Recorded from west
Scotland and Orkney (Shetland records
require confirmation).
Recorded off NW Scotland and Orkney.
Sporadic occurences further south in
Britain.The major maerl bed biotope in
Scotland.
Present from Mauritania and the
Mediterranean to the British Isles.
Recorded off west Scotland and in
Orkney.
Present from Cameroon to the British
Isles. Southern species recorded as far
north as Anglesey (record needs
checking) and Galway Bay
Northern species recorded on west coast
of Scotland, Shetland and Orkney. Also
occurs on east coast and in
Northumberland. This is its southern limit
and does not occur in Northern Ireland.
Present from Morocco to the British Isles
including Shetland. Recorded off west
Scotland, Orkney and Shetland
Southern species recorded from Morocco
to Cornwall & Devon. In Northern Ireland,
rare in littoral, not uncommon in
sublittoral. Absent from Scotland.
Present from Morocco to the British Isles.
Recorded off west Scotland, Orkney and
Shetland
Present from Morocco to the British Isles.
Recorded north to Anglesey and with
some records for Jura and Islay. Very
rare in northern Ireland.
Present from Morocco and the Azores to
the British Isles. Recorded off the west
coast of Scotland and Orkney and in
north-east England. Not recorded from
Shetland.
Present from the Mediterranean and
southern Spain to Norway and the
Faroes. Recorded in SW Scotland and
Orkney.
Present from the Canary Island to British
Isles. Distribution in Scotland restricted to
a few locations on the west coast.
Present from northern Spain to the British
Isles. Southern species with a few
records from the Outer Hebrides and
outer Solway Firth in Scotland.
Present in northern France and the British
Isles. The only Scottish records are from
Islay and St Kilda.
57
S
N
S
N
S
S
S
S
S
S
S
S
S
Odonthalia dentata**
A red alga
Stilophora tenella (= S.
A brown alga
rhizoides)
Sphacelaria arctica*
A brown alga
Sphacelaria mirabilis*
a brown alga
Sphacelaria plumosa
a brown alga
Halopteris filicina
a brown alga
Dictyopteris
membranacea**
a brown alga
Taonia atomaria*
a brown alga
Carpomitra costata*
a brown alga
Chorda tomentosa
a brown alga
Laminaria ochroleuca
a kelp
Bifurcaria bifurcata*
a brown alga
Cystoseira baccata
a brown alga
Cystoseira
foeniculaceus
a brown alga
Cystoseira
tamariscifolia
a brown alga
Present from the British Isles to
Spitzbergen. Recorded throughout
Scotland and as far south as the Isle of
Man on the west coast of Britain and
Flamborough on the east coast.
Present from France to Scotland.
Recorded from west Scotland, Orkney
and Shetland
Northern species only recorded in
Shetland in the UK. Also occurs in
Denmark, Baltic, Norway & Greenland.
Northern species recorded in north
Wales, Cheshire, around Scotland to
north-east England at Berwick-uponTweed.
Northern species recorded reliably in west
Wales, Cheshire, around Scotland to
north-east England at Flamborough
Head. Rare in Northern Ireland.
Present from the Azores and Portugal to
Scotland. Recorded from western
Scotland. (Shetland record requires
confirmation)
Present from the Azores and Portugal to
the British Isles. A southern species
present in large amounts only in the
extreme south-west of Britain with a few
records from west Scotland.
Present from the Azores and
Portugal/southern Spain to south-west
Britain to the Isle of Man and Ireland.
Southern species recorded in Channel
Islands and southern UK as far north as
the Isle of Man and Donnegal. Rare in
Ireland and only a few records from the
Outer Hebrides.
Northern species recorded from west
Scotland, Firth of Forth and Northern
Ireland.
Southern species currently recorded as
far north as Lundy.
Southern species recorded from southern
Spain to England and Wales. Records
from NW Ireland require checking.
Present from southern Spain and
Portugal to south-west Britain and
western Ireland.
A southern species only recorded in the
south-west of England.
Recorded as far north as the mid outer
hebrides, south-west Uist. Also recorded
in Arisaig, south of Mallaig.
58
N
S
N
N
N
S
S
S
S
N
S
S
S
S
S
Ascophyllum nodosum
ecad mackaii*
Knotted wrack
Fucus distichus
distichus**
A brown alga
Fucus evansecens*
A brown alga
Codium adhaerens*
A green alga
Codium tomentosum
A green alga
Only recorded from Scotland in the UK
and in a few locations in Ireland.
Temperature may be important in
distribution.
Northern species recorded from Scotland
to the Arctic. Not recorded in Northern
Ireland.
Present from Shetland and the Danish
Baltic to the arctic. The only British
records are from Shetland
Present Portugal to the British Isles.
Scottish records limited to Argyll and Mull.
Present from the Mediterranean and
Azores to northern Scotland. Also
recorded in the Netherlands. Recorded in
west Scotland and Orkney
59
N
N
N
S
S
60
Appendix 5. Basic information for species with a limited geographical range in or near
Scotland whose distribution might change due to global warming.
The species names used in the following information sheets are those used in The Species
Directory of the Marine Fauna and Flora of the British Isles and Surrounding Seas (Howson
& Picton, 1997) where authorities for species names can be found. Pentapora fascialis
(Pallas) is considered (Hayward & Ryland 1999) to include Pentapora foliacea, the name
used in the Species Directory.
References given in the text of this appendix are included in the list of references following
the body of the report.
61
62
1. Axinella dissimilis (=Axinella polypoides)
Common name:
Distribution:
Recorded as far north as Mull,
Northern Ireland and Anglesey
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Epilithic, sublittoral (Hayward & Ryland, 1995)
Notes:
This is a conspicuous species which could provide an easily identified
species suitable for monitoring for changes in distribution.
Legislative
protection:
None
63
2. Ciocalypta penicillus
Common name:
Distribution:
Recorded as far north as Northern
Ireland and Anglesey
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
On horizontal rock surface, sometimes partially covered by sand or silt
(Hayward & Ryland, 1995)
Notes:
This is a conspicuous species which could provide an easily identified
species suitable for monitoring for changes in distribution.
Legislative
protection:
None
64
3. Thuiaria thuja
Common name:
Bottle-brush hydroid
Distribution:
A northern species recorded south to
off Northumberland in the British Isles
Records from the Firth of Forth,
Orkney, Shetland and Lewis in
Scotland.
Map shows likely current distribution
using the following information
sources:
Cornelius, 1995; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
On shells and similar substrata, 2 to 800m (Hayward & Ryland, 1995)
Notes:
This is a conspicuous species which could provide an easily identified
species suitable for monitoring for changes in distribution. The
apparent lack of this species on the NE coast of Scotland is most likely
due to a lack of survey information. One hundred years ago this
species was commonly recorded further south in the English Channel
(Cornelius, 1995).
Legislative
protection:
None
65
4. Gymnangium montagui
Common name:
Yellow feathers hydroid
Distribution:
Southern species extending as far
north as Northern Ireland and
Anglesey
Map shows likely current distribution
using the following information
sources:
Cornelius, 1995; Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
On algae, shells and rock (Hayward & Ryland, 1995). Usually in deep
coastal water.
Notes:
This is a conspicuous species which could provide an easily identified
species suitable for monitoring for changes in distribution.
Reproductive season in August off Roscoff (Cornelius, 1995).
Legislative
protection:
None
66
5. Alcyonium glomeratum
Common name:
Red sea fingers
Distribution:
A southern species with scattered
records from the west coast of
Scotland.
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
In gullies or caves sheltered from wave action; below 10-50m (Manuel,
1981; Hayward & Ryland, 1995)
Notes:
Distribution is mainly restricted to wave sheltered locations except in the
Isles of Scilly where it is widespread on sheltered and exposed coasts.
Legislative
protection:
None
67
6. Swiftia pallida
Common name:
Northern sea-fan
Distribution:
Only recorded in west Scotland and
St Kilda in the British Isles. Also
occurs in deep water in the Bay of
Biscay and Meditteranean.
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
On rocks and boulders between 18 and 60m (Manuel, 1981)
Notes:
Typically northern or cold water (deep water) species which is usually
present in small numbers except at a few locations. It is a host for the
nationally rare sea anemone, Amphianthus dohrnii. A conspicuous,
easily identified species, but it may be confused with Eunicella
verrucosa.
Legislative
protection:
None
68
7. Eunicella verrucosa
Common name:
Pink sea-fan
Distribution:
Southern species recorded as far
north as NW Ireland and SW Wales.
Recorded east in the English Channel
to Portland. Also common in SW
Europe, Mediteranean and NW
Africa.
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Attached to rocks deeper than 10m (Hayward & Ryland, 1995).
Notes:
A large, easily recognisable species suitable for the purposes of
monitoring change. Recorded as far east as Margate in historical
records (Manuel, 1981). Care is required to distinguish this species
from Swiftia pallida.
Legislative
protection:
UK Species Action Plan
Wildlife and Countryside Act (1981): Schedule 5
69
8. Funiculina quadrangularis
Common name:
Tall sea pen
Distribution:
Recorded on the north and west
coasts of Ireland and Scotland. Also
occurs in the Mediterranean.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
In mud on sheltered shores especially in sea lochs; sublittoral to 15m
(Hayward, Nelson-Smith & Shields, 1996). These habitat requirements
are very specific resulting in its restricted distribution.
Notes:
This species is only found in inshore waters in Scotland where it is a
dominant feature of deep undisturbed and extremely sheltered
sediments. Although not necessarily restricted to Scotland because of
cold water, consideration of possible input of warmer waters is required.
Legislative
protection:
UK Biodiversity Action Plan: Species statement
70
9. Anemonia viridis
Common name:
Snakelocks anemone
Distribution:
Widely recorded on the west coast of
Britain and Orkney but not recorded
in Shetland during extensive surveys.
Map shows likely current distribution
using the following information
sources:
Crisp & Southward, unpub data;
Lewis, 1964; Hawkins & Jones, 1992;
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Eulittoral and sublittoral fringe pools on sheltered to moderately
exposed shores; prefers areas open to light (Hawkins & Jones, 1992;
Hayward & Ryland, 1995)
Notes:
Unable to tolerate prolonged conditions of extreme cold (Manuel, 1981).
May be present on the NE coast of Scotland but records are
unavailable. Absence from Shetland indicated by wide survey work. A
conspicuous species suitable for monitoring.
Legislative
protection:
None
71
10.
Bolocera tuediae
Common name:
Deeplet anemone
Distribution:
The only records in Britain are off the
south-east coast of Scotland and
north east cost of England and south
west coasts of Scotland.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Sublittoral below 20m (Hayward & Ryland, 1995). Offshore species
occuring on rocks, stones and shells (Manuel, 1981).
Notes:
A northern species, although surprisingly not recorded from
Orkney/Shetland. May be long lived and with care can be readily
identified and suitable for monitoring the effects of climate change.
Legislative
protection:
None
72
11.
Aulactinia verrucosa (=Bunodactis verrucosa)
Common name:
Gem anemone
Distribution:
Southern species recorded at at few
locations in SW Scotland and
Shetland
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Manuel, 1981;
MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Intertidal in crevices and pools (especially with Corallina) or attached to
rock beneath a layer of sand or gravel on sheltered to exposed shores;
rarely found below low water on sheltered to exposed shores (Hayward
& Ryland, 1995).
Notes:
A southern species, the record from Shetland requires checking. The
habitat in which it is found is rather specialised and careful searching is
required for this species.
Legislative
protection:
None
73
12.
Phellia gausapata
Common name:
Distribution:
Northern species recorded in west
Scotland and Shetland and Northern
Ireland.
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Vertical bedrock usually at exposed locations.
Notes:
A somewhat inconspicuous sea anemone which requires careful
observation skills but as a northern species it should be included in any
future monitoring.
Legislative
protection:
None
74
13.
Amphianthus dohrnii
Common name:
Sea fan anemone
Distribution:
Recorded in west Scotland and a few
locations in SW Britain.
Map shows likely current distribution
using the following information
sources:
Anon, 1999; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Sea fans (Eunicella verrucosa and Swiftia pallida) and sometimes
tubular hydroids, especially Tubularia indivisa.
Notes:
The distribution of this species follows that of the sea fan Swiftia pallida
in Scotland. However, it is found at only a few southern sites where
Swiftia occurs. Since the anemone is found in south-west England, it
may be a southern species and more research is needed to establish if
its restricted distribution in Scotland is the result of seawater
temperatures.
Legislative
protection:
UK Biodiversity Action Plan: Species statement
75
14.
Corynactis viridis
Common name:
Jewel anemone
Distribution:
A southern species. Recorded on
open wave exposed coasts in
western Scotland, Orkney and
Shetland in Scotland.
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Common in depths below 5m beneath overhangs and in caves; also
found at low water in shaded places (Hayward & Ryland, 1995). Often
forms dense aggregations on vertical rock faces (Manuel, 1981).
Notes:
Occurrences in Scotland are generally of smaller patches or sparser
colonies than occur farther south in the British Isles.
Legislative
protection:
None
76
15.
Sabellaria alveolata
Common name:
Honeycomb worm
Distribution:
Only Scottish records are from the
Solway Firth and off Lewis.
MERMAID record from Outer
Hebrides requires checking.
Map shows likely current distribution
using the following information
sources:
Crisp & Southward, unpubl. data;
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Moderately exposed to exposed shores or in strong currents; lower
eulittoral and sublittoral fringe; Needs high water movement to supply
coarse sand (Hawkins & Jones, 1992)
Notes:
Larval settlement patchy and spasmodic; reefs usually between 5 and 7
years old (Hawkins & Jones, 1992). Suitable habitats for this species
may be rare in SW Scotland.
Legislative
protection:
UK Biodiversity Action Plan: Species statement
77
16.
Chthamalus montagui
Common name:
Montagu’s punctate barnacle
Distribution:
Southern; common on west coasts of
Scotland; present in Orkney and
Shetland and rare at a few places on
the east coast.
Map shows likely current distribution
using the following information
sources:
Unpublished surveys of Southward &
Crisp (1953-1962); Crisp, Southward
& Southward, 1981; Burrows,
Hawkins & Southward, 1992;
Hawkins & Jones, 1992; Picton &
Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
High to mid eulittoral on exposed to moderately sheltered shores
(Hawkins & Jones, 1992)
Notes:
Hermaphrodite; normally cross fertilizing but can still self impregnate if
necessary; planktonic larvae for ~4 weeks (Burrows, 1988; Hawkins &
Jones, 1992); breeding period, period of larval settlement and density of
recruits are all reduced near northern limits of distribution; brood from
May-August; cyprids settle July-September (Wales) (Kendall & Bedford,
1987), July-October (Devon) (Pannacciulli, 1995); will only breed above
15°C, optimum at 24-25°C (Patel & Crisp, 1960); may not breed every
year in Scotland. The abundance of C. montagui and C. stellatus has
been shown to be sensitive to short term change in seawater and air
temperatures. This may provide a sensitive early indication of change.
Legislative
protection:
None
78
17.
Chthamalus stellatus
Common name:
Poli’s stellate barnacle
Distribution:
Southern species recorded off west
Scotland, Shetland and Orkney.
Map shows likely current distribution
using the following information
sources:
Crisp, Southward & Southward, 1981;
Hawkins & Jones, 1992; Burrows,
Hawkins & Southward, 1992;
O'Riordan, Myers & Cross, 1995;
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Mid to low eulittoral on exposed shores (Hawkins & Jones, 1992).
Favours more exposed sites than C. montagui (Crisp, Southward &
Southward, 1981).
Notes:
Hermaphrodite; planktonic larvae for 4-6 weeks (Hawkins & Jones,
1992). The abundance of C. montagui and C. stellatus has been
shown to be sensitive to short term change in seawater and air
temperatures. This may provide a sensitive early indication of change.
Legislative
protection:
None
79
18.
Palinurus elephas
Common name:
Crawfish
Distribution:
Previously widely distributed in south
west Britain in the British Isles but
has declined in the past 20 years.
Recorded on the west coast of
Scotland, Orkney and Shetland. Also
a few records from the east coast of
Scotland.
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Ansell & Robb,
1977; Hunter, Shackley & Bennett,
1996; Picton & Costello, 1998;
MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
From 5 to 70m (Ansell & Robb, 1977) on rocky habitats.
Notes:
This species occurs sporadically and has declined in abundance in SW
England during the past 30 years. Larval supply may be affected by
water quality conditions (K. Hiscock, unpubl. data).
Legislative
protection:
None
80
19.
Lithodes maia
Common name:
Northern stone crab
Distribution:
Northern species recorded in west
Scotland and Shetland
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Offshore from 10 to 100m (Hayward & Ryland, 1995)
Notes:
A northern species although occurring in inshore (possibly colder) areas
further south in Scotland. A conspicuous, easily recognizable species
(although sometimes confused with Maja squinado) suitable for
monitoring any impact of climate change. Rare in Celtic Sea (AJS,
unpubl. data).
Legislative
protection:
None
81
20.
Maja squinado
Common name:
Thorn back spider crab
Distribution:
Only extends as far north as the Isle
of Man and NW Ireland
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Clark, 1986;
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Low water to 73m (Ingle, 1980)
Notes:
Larvae October & November (Isle of Man) (Ingle, 1980). Usually
recorded in small numbers at the northern most limit of its distribution.
A conspicuous easily recognised species but may be sometimes
confused with Lithodes maia. Suitable for monitoring.
Legislative
protection:
None
82
21.
Goneplax rhomboides
Common name:
Angular crab
Distribution:
A southern species recorded from a
few locations on the west coast of
Scotland.
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Clark, 1986;
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Lower shore to 100m burrowing in mud and sandy mud (also found
between 146-1478m) (Ingle, 1980).
Notes:
Zoeae September & October (Irish Sea) (Ingle, 1980).
Legislative
protection:
None
83
22.
Xantho incisus
Common name:
Montagu's crab
Distribution:
Recorded on SW coast of Scotland
Map shows likely current distribution
using the following information
sources:
Clark, 1986; Picton & Costello, 1998;
MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Lower shore to 37m (Ingle, 1980)
Notes:
Ovigerous May-July, larvae May-July & September-October (Galway
Bay) (Ingle, 1980)
Legislative
protection:
None
84
23.
Margarites helicinus
Common name:
Pearly top shell
Distribution:
Northern species recorded in both
west and east Scotland, Shetland and
Orkney
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Seaward, 1982;
1990; 1993; Picton & Costello, 1998;
MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Low shore and sublittoral, under stones, in pools and on algae
(Hayward & Ryland, 1995)
Notes:
An easily identified northern species of intertidal gastropod suitable for
monitoring.
Legislative
protection:
None
85
24.
Gibbula umbilicalis
Common name:
Flat top shell
Distribution:
A southern species commonly
recorded on the west coast of Britain
and present in Orkney. Also occurs
on the east coast of Scotland but not
in Shetland.
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Lewis, 1964;
Seaward, 1982,, 1990,, 1993;
Hawkins & Jones, 1992; Picton &
Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Mid to lower eulittoral on sheltered to moderately exposed shores
(Hawkins & Jones, 1992)
Notes:
Gonad development begins in April/May; synchronized initial major
spawning in August followed by further small releases of gametes;
reproductive season not always successful at northern limits of
distribution; mature at 2 years old (Garwood & Kendall 1985); larvae
settle within a few days; life span about 10 years (Hayward & Ryland
1995; Hayward, Nelson-Smith & Shields,1996). Widely distributed in
Scotland but not present in Shetland. Care needs to be taken in
separating this species from Gibbula cineraria, but abundances whould
be assessed in relation to any effect of climate change.
Legislative
protection:
None
86
25.
Monodonta lineata
Common name:
Toothed topshell
Distribution:
Southern species which reaches its
northern limits in Northern Ireland and
Anglesey
Map shows likely current distribution
using the following information
sources:
Lewis, 1964; Seaward, 1982; 1990;
1993; Hawkins & Jones, 1992; Picton
& Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Mid to upper eulittoral on moderately sheltered to exposed shores
(Hawkins & Jones 1992); avoids excessive exposure and shingle or
sand (Hayward & Ryland 1995)
Notes:
Gonad development begins in April/May; synchronized initial major
spawning in July followed by further small releases of gametes;
reproductive season not always successful at northern limits of
distribution; mature at 2 years old (Garwood & Kendall 1985). An
easily recognized intertidal species that needs specific searching for.
May occur in very small numbers where recruitment is from distant
populations. However, to spread further north, populations would need
to be significantly large enough to be self-recruiting.
Legislative
protection:
None
87
26.
Tectura testudinalis (=Tectura tessulata)
Common name:
Tortoiseshell limpet
Distribution:
A northern species commonly
recorded throughout Scotland but
reaching its southern limit in the Irish
Sea in the British Isles.
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
On boulders and small stones (especially with Lithothamnion); low
water to 50m (Hayward & Ryland, 1995)
Notes:
A readily identifiable intertidal limpet although sometimes confused with
Acmaea virginea (a species that has a more southern distribution).
Legislative
protection:
None
88
27.
Patella depressa
Common name:
Black-footed limpet
Distribution:
Southern species which reaches its
northern limits at Anglesey
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Moderately exposed to exposed shores; eulittoral, commonest around
MTL (Hawkins & Jones, 1992)
Notes:
Protandrous hermaphrodite; gametes released into the sea to form
planktonic larvae; settle in pools after 4 days (Hawkins & Jones, 1992)
Legislative
protection:
None
89
28.
Patella ulyssiponensis (=Patella aspera)
Common name:
Distribution:
Commonly recorded on the west
coast of Britain and Orkney. Also
occurs on east coast of Scotland and
Shetland
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Seaward, 1982;
1990; 1993; Hawkins & Jones, 1992;
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Exposed coasts below MLWN or in pools on midshore (Hawkins &
Jones, 1992)
Notes:
Protandrous hermaphrodite; gametes released into the sea to form
planktonic larvae; settle in pools after 4 days (Hawkins & Jones, 1992)
Legislative
protection:
None
90
29.
Calyptraea chinensis
Common name:
Chinaman's hat
Distribution:
Rarely recorded in SW Scotland and
west Ireland.
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Seaward, 1982;
1990; 1993; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Low water to 20m, on and under stones, often on sheltered shores with
soft substrat (Hayward & Ryland, 1995)
Notes:
A warm water species.
Legislative
protection:
None
91
30.
Atrina fragilis (=Pinna fragilis)
Common name:
Fan mussel
Distribution:
Present in south west England and
western Scotland in the British Isles.
Recorded off the west of Scotland
(especially around Mull), Shetland,
Orkney and the Moray Firth. Rarely
encountered.
Map shows likely current distribution
using the following information
sources:
S. Smith, pers. comm.; Woodward,
1985; Seaward, 1982; 1990; 1993
Preferred habitat:
Part buried in mud, sandy mud or gravel, attached to stones or pieces
of shell; offshore (Tebble, 1966; Hayward, Nelson-Smith & Shields,
1996)
Notes:
This species seems to be naturally rare in occurrence but populations
are adversely effected by mobile fishing gears. Individuals may be long
lived. More needs to be understood about the reproductive biology and
recruitment of this species.
Legislative
protection:
UK Species Action Plan
Wildlife and Countryside Act (1981): Schedule 5
92
31.
Ostrea edulis
Common name:
Native oyster
Distribution:
Recorded from Norway to the
Mediterranean and the Black Sea.
Widely distributed around the British
Isles.
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
On course bottoms from ELWS to 80m (Hayward & Ryland, 1995).
Associated with highly productive estuarine and shallow coastal water
habitats (Anon, 1999).
Notes:
Breeding season is from May to August (Hayward, Nelson-Smith &
Shields, 1996). Populations have become reduced or extinct partly due
to fishing. This species has declined very significantly, at least in
England and Wales, in the past 100 years or so. The causes are
uncertain and whether climate change might affect distribution is also
uncertain. However, as a valued species, careful consideration of the
likely impact of change is needed.
Legislative
protection:
UK Species Action Plan
93
32.
Thyasira gouldi
Common name:
Northern hatchet shell
Distribution:
Northern species recorded from
upper Loch Etive, Loch Eil and Loch
Sunart. The status at the latter two
sites is currently unknown. These are
the most southerly European
populations of this species.
Map shows likely current distribution
using the following information
sources:
Anon, 1999
Preferred habitat:
In anoxic soft mud, silt clay or clay mud sediments. Found at a depth
between a few and several 100 m (Anon, 1999).
Notes:
Occurs in patches. May not be able to tolerate rapid increases in water
temperature. A northern species which prefers low water temperatures
but has acclimatised to warmer bottom temps (7-13°C) in upper Loch
Etive (Anon, 1999). This species is a ‘classic’ relict species, surviving in
the cold deep waters of a few sea lochs. It is believed to be left over
from previous wider distributions during colder times.
Legislative
protection:
UK Species Action Plan
Wildlife and Countryside Act (1981): Schedule 5
94
33.
Gari depressa
Common name:
Large sunset shell
Distribution:
Southern species, just extending
north into west Scotland
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Seaward, 1982;
1990; 1993; Picton & Costello, 1998;
MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Low shore to 50m in coarse sand or gravel (Tebble, 1966; Hayward &
Ryland, 1995)
Notes:
Legislative
protection:
None
95
34.
Pentapora fascialis (=Pentapora foliacea)
Common name:
Ross
Distribution:
A southern species abundant in
southwest Britain and recorded off
west Scotland including at St Kilda.
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Sublittoral, either below edge of kelp forest or on Laminaria holdfasts;
most abundant between 25-34m; on rocky, current swept bottoms, on
bedrock or attached to stones (based on Hayward & Ryland, 1979).
Notes:
A conspicuous, easily recognized species that is much more abundant
and widely distributed in the south-west. Occurs on a wide range of
tide exposed and wave exposed habitats.
Legislative
protection:
None
96
35.
Asterina gibbosa
Common name:
Cushion star
Distribution:
Recorded off west Scotland and
Orkney
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Lewis, 1964;
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Rock pools to 125m subtidal; lives on or below stones, also found
among algae, sponges and Zostera (Mortensen, 1927)
Notes:
Breeding season, May-June; eggs attached to stones; no pelagic larval
stage (Mortensen, 1927). This small cushion star needs careful
searching for but occurs intertidally and should provide a good indicator
of change in distribution. Care is required to separate this species from
Asterina phylactica.
Legislative
protection:
None
97
36.
Leptasterias muelleri
Common name:
Distribution:
A northern species recorded widely
around the British Isles except on the
south coast.
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Under stones
Notes:
Breeding season in early spring (March to April) (Mortensen, 1927).
Legislative
protection:
None
98
37.
Paracentrotus lividus
Common name:
Purple sea urchin
Distribution:
A southern species which is abundant
in parts of south-west Ireland but has
only sporadic recorded occurrences
in south west England and at a few
locations on the west coast of
Scotland.
Map shows likely current distribution
using the following information
sources:
Crisp & Southward, unpubl. data;
Lewis, 1964; Hawkins & Jones, 1992;
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Low shore pools and sublittoral on moderately exposed shores
(Hawkins & Jones, 1992)
Notes:
Gonad growth autumn to winter (maximum at low tempertures 10°C),
maturing spring to early summer, followed by spawning; initial spawning
triggered by either 15 hour day length (Brittany) or temperature of 1315°C (Ireland); double spawnings have been found but single more
likely in Ireland (Byrne, 1990; Spirlet et al., 1998); spawning ends when
water temperature reaches 17°C. Declined in Ireland due to fishery.
Legislative
protection:
None
99
38.
Strongylocentrotus droebachiensis
Common name:
Green sea urchin
Distribution:
A northern species confined to the
east coast of the British Isles.
Probably occurs on all North Sea
coasts of Britain.
Map shows likely current distribution
using the following information
sources:
Mortensen, 1927; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Infralittoral fringe down to 1200m (Hayward & Ryland, 1995). May bore
holes (Mortensen, 1927).
Notes:
Breeding season in early spring (Mortensen, 1927).
Legislative
protection:
None
100
39.
Holothuria forskali
Common name:
Cotton spinner
Distribution:
A southern species that is abundant
in parts of south west England.
Recorded off west Ireland and a few
locations off west Scotland around
Rum.
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Shallow water (Mortensen, 1927)
Notes:
Breeding season in summer months (Mortensen, 1927). A widely
distributed species in SW Britain, easily recognised and suitable for
monitoring studies. Could be confused with Cucumaria frondosa, so
care needed in identification.
Legislative
protection:
None
101
40.
Cucumaria frondosa
Common name:
Northern sea cucumber
Distribution:
A northern species widely recorded in
Shetland, also occurs in Orkney
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Low shore to 200m sublittoral; especially amoung Laminarians
(Mortensen, 1927)
Notes:
Breeding season, February-March (later further north) (Mortensen,
1927). This far northern species is readily identified although
sometimes confused with Holothuria forskali. Numbers are usually very
small at any one location.
Legislative
protection:
None
102
41.
Styela gelatinosa
Common name:
Distribution:
Only British population is in Loch Goil
(Clyde Sea). Also occurs in
Scandinavia and Iceland.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Soft mud, in very sheltered conditions (Anon, 1999).
Notes:
The natural heritage importance of this species (it is only known in the
British Isles from one location in Scotland) means that consideration
should be given to the likely effects of climate change. Cold water
species.
Legislative
protection:
UK Biodiversity Action Plan: Species statement
103
42.
Labrus mixtus (=Labrus bimaculatus)
Common name:
Cuckoo wrasse
Distribution:
Commonly recorded off north and
west Scotland, Orkney and Shetland.
Also occurs in the Firth of Forth
Map shows likely current distribution
using the following information
sources:
Bruce et al., 1963; Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Littoral 2-200m, mainly 40-80m (Whitehead et al., 1986)
Notes:
Reproductive season, May-July (North Sea and Channel) (Whitehead et
al., 1986). Although widely distributed, records are sporadic and
numbers are small. An easily recognised species suitable for
monitoring changes, particularly in abundance.
Legislative
protection:
None
104
43.
Thorogobius ephippiatus
Common name:
Leopard-spotted goby
Distribution:
Recorded off west Scotland, Orkney
and in the Firth of Forth
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Inshore in or near crevices of steep rock faces, to 40m (usually 6-12m);
rarely in deep intertidal pools (Whitehead et al., 1986)
Notes:
Reproductive season, May-July (Plymouth); mature at 3 to 4 years
(Whitehead et al., 1986). Although widely distributed in Scotland this
species is apparently absent from Shetland. Therefore it should be
included in any studies of changes in distribution.
Legislative
protection:
None
105
44.
Bonnemaisonia hamifera
Common name:
A red alga
Distribution:
The tetrasporophyte phase
(Trailliella) is widely distributed from
Mauritania to northern Norway but the
gametophyte (Bonnemaisonia) phase
is only found between Spain and
south-west England. In Scotland,
tetrasporophyte phase extends to
Shetland, gametagial phase extends
to Argyll.
Map shows likely current distribution
using the following information
sources:
Norton, 1985; Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Gametangial phase sublittoral attached to other algae, occasionally
lower littoral in deep pools; tetrasporangial phase epiphytic or (epilithic)
lower littoral to 8m sublittoral (Dixon & Irvine, 1977)
Notes:
Tetrasporangial found further north than gametangial phase;
gametangial phase found throughout the year, best growth spring and
early summer; tetrasporangial phase occurs as dense clumps in
summer and isolated filaments in winter; spermatangial plants
infrequent in Britain; can spread vegetatively (Dixon & Irvine, 1977).
Northern limit of gametophyte corresponds to the 13°C October
isotherm. Tetrasporophyte reaches its limit further north at the 10°C
summer isotherm. The northern lethal boundary is not reached since
both forms can survive water temperatures below 0°C (Luning, 1990).
Species introduced from Japan (~1890). Abundance: tetrasporophyte
is common whereas gametophyte is only common in the south and
west.
Legislative
protection:
None
106
45.
Jania rubens
Common name:
Distribution:
Southern species occuring as far
north as Norway. In British Isles
recorded northwards to west
Inverness and Aberdeen. Very rare
in Northern Ireland.
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Epiphytic on Cladostephus, Cysteroseira and Halopithys in British Isles;
sublittoral to 8m; extreme shelter to exposed pools (Irvine &
Chamberlain, 1994)
Notes:
Monoecious; annual; fronds arise in Autumn, fertile by April; can
regenerate from lateral branches (esp in warm water); growth from 1030 °C, spores fail at 10 °C, spores attach at 17-20 °C, fertile between
11-17 °C; gametangial and tetrasporangial plants equally common
(Irvine & Chamberlain, 1994). Abundance: common on west coast only.
Recently died back in southern North Sea (Scott & Tittley, 1998). An
easily recognised species although it is sometimes confused with
Corallina officinalis. Suitable for intertidal surveys of distributional
changes.
Legislative
protection:
None
107
46.
Lithothamnion glaciale
Common name:
Maerl
Distribution:
Present from northern British Isles to
Arctic Russia. A northern species
commonly recorded in west Scotland,
Shetland, Orkney and the Firth of
Forth. Common in Northern Ireland.
Recorded reliably south to Lundy and
to Flamborough on the east coast of
England.
Map shows likely current distribution
using the following information
sources:
Irvine & Chamberlain, 1994, Norton,
1985; Picton & Costello, 1998;
MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Epilithic on bedrock and pebbles; lower littoral in pools and sublittoral to
34m; sheltered habitats with some water movement (Irvine &
Chamberlain, 1994). Found in variable salinity.
Notes:
Gametangial plants dioecious; common; branches can detatch and
contribute to maerl; fast growing; bisporangial conceptacles present
throughout year; capable of rapid growth at 13.5°C (Irvine &
Chamberlain, 1994). Abundance: common.
Legislative
protection:
None
108
47.
Mesophyllum lichenoides
Common name:
Distribution:
Southern species extending from the
Canaries and Mediterranean to the
British Isles. Recorded off west
Scotland as far north as Orkney.
(Shetland records require
confirmation).
Map shows likely current distribution
using the following information
sources:
Norton, 1985; Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Epiphytic on Corallina; lower littoral to 8m sublittoral; fairly to very
exposed shores (Irvine & Chamberlain, 1994)
Notes:
Gametangial concepticles dioecious; perennial; gametangial
conceptacles from February-April, tetrasporangial for April to December
(Irvine & Chamberlain, 1994). Abundance: locally common. Good
recognisable species to monitor for spread to east coast.
Legislative
protection:
None
109
48.
Phymatolithon calcareum
Common name:
Maerl
Distribution:
Widely distributed on south and west
coasts of Britain from Dorset to
Shetland.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid), MarLIN
(www.marlin.ac.uk)
Preferred habitat:
On a mixture of substrates between 1 and 30m on sheltered to exposed
shores. Usually found with Lithothamnion glaciale in Scotland.
Notes:
Supports a wide range of species some of which occur mainly or only in
maerl biotopes. Distribution in the NE Atlantic seems to be determined
by seawater temperature as well as presence of suitable habitats and
change is likely in rising temperatures. This species may also be
dredged commercially. No crustose forms in Britain so propagation
must be virtually entirely vegetative (MarLIN, www.marlin.ac.uk). Often
confused with Lithothamnion coralloides. This species forms the major
maerl bed biotope in Scotland.
Legislative
protection:
Part of Habitats Directive Annex V:
UK Biodiversity Action Plan: Species statement
110
49.
Callophyllis cristata
Common name:
Distribution:
Northern species recorded on west
coast of Scotland, Shetland and
Orkney. Also occurs on east coast
and in Northumberland. This is its
southern limit and does not occur in
Northern Ireland.
Map shows likely current distribution
using the following information
sources:
I. Tittley (unpubl. data), Norton, 1985;
MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Epiphytic on Laminaria; upper sublittoral to at least 30m; sheltered and
moderately exposed; full salinity (Irvine, 1983)
Notes:
Gametangial plants dioecious; perenial; (southern reports dubious?);
cystocarps recorded from June-October, tetrasporangia from June-July
(GB) (Irvine, 1983). Abundance: common.
Legislative
protection:
None
111
50.
Stenogramme interrupta
Common name:
Distribution:
Southern species recorded from
Morocco the Cornwall & Devon. In
Northern Ireland, rare in littoral, not
uncommon in sublittoral. Absent from
Scotland.
Map shows likely current distribution
using the following information
sources:
Norton, 1985; Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Epilithic; sublittoral to 13m; sheltered areas on small stones, shell,
gravel and mud (Dixon & Irvine, 1977). Usually in areas exposed to
moderate tidal streams.
Notes:
Gametangial plants dioecious; perrenial, plants sterile in first year,
fertile in summer of second; tetrasporangia and cystocarps occur
throughout year, most abundant July-Sept (Dixon & Irvine, 1977). This
species is found in a fairly specific habitat (tide swept cobbles) and is
readily recognised by its broken mid ribs. Suitable for any studies of
distributional changes.
Legislative
protection:
None
112
51.
Rhodymenia holmesii
Common name:
Distribution:
Present from Morocco to the British
Isles. Recorded north to Anglesey
and with some records for Jura and
Islay. Very rare in northern Ireland.
Map shows likely current distribution
using the following information
sources:
I. Tittley (unpubl. data), Picton &
Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Epilithic (in soft rock); tolerate sand cover and some exposure; lower
littoral and sublittoral to at least 25m (Irvine, 1983)
Notes:
Gametangial plants dioecious; young fronds appear February-March;
spermatangia recorded for November, cystocarps and tetrasporangia
for April, June-September (Irvine, 1983). Abundance: rare/sporadic in
Scotland.
Legislative
protection:
None
113
52.
Sphondylothamnion multifidum
Common name:
Distribution:
Southern species recorded from the
Canaries & Meditteranean to the
British Isles. Scottish records from
Inverness, Ross & Cromarty. Very
rare in Northern Ireland.
Map shows likely current distribution
using the following information
sources:
Norton, 1985, Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
On bedrock from shady low shore pools to 30m subtidal, also on mobile
substrates (mearl/pebbles), tolerant of sand scour, very sheltered to
very exposed (Maggs & Hommersand, 1993)
Notes:
Annual, gametangial plants found on S coast of England; may be
confused; erect fronds annual; spermatangia recorded in July, procarps
and cystocarps in July and September, tetrasporangia in JuneSeptember (Maggs & Hommersand, 1993). Abundance: common on
west coast only. Becoming more common in Scotland.
Legislative
protection:
None
114
53.
Odonthalia dentata
Common name:
Distribution:
Northern species recorded
throughout Scotland and as far south
as the Isle of Man and Northern
Ireland (County Mayo & Down). Also
recorded on the east coast as far
south as Flamborough. Occurs from
Spitzbergen to British Isles.
Map shows likely current distribution
using the following information
sources:
Norton, 1985; Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
On bedrock, boulders, cobbles (also epiphyte on Laminaria); pools,
ELW to 20m; moderately to extermely exposed nad sheltered sites with
strong tide; most abundant in shallow kelp forests (Maggs &
Hommersand, 1993)
Notes:
Plants dioecious; perennial (up to 9yrs); easiliy identified; details of
growth and repro form IoM; new growth begins in February, stops by
July at maximum weight, fronds lost throughout summer and autumn;
spermatangia in November-February, cystocarps in December-June,
and tetrasporangia in November- June (IoM); in Scotland cystocarps
and tetrasporangia occur until August (Maggs & Hommersand, 1993).
Adundance: common in north. A readily recognisable and often
abundant red alga whose southern limit near to the SW coast of
Scotland makes it a good indicator species suitable for any monitoring
study.
Legislative
protection:
None
115
54.
Sphacelaria arctica
Common name:
Distribution:
Northern species only recorded in
Shetland in the UK. Also occurs in
Denmark, Baltic, Norway &
Greenland.
Map shows likely current distribution
using the following information
sources:
I. Tittley (unpubl. data)
Preferred habitat:
Sand scoured rocks, littoral pools and sublittoral. Can tolerate low
salinity.
Notes:
Grows well at 4-12°C. Rare species which is sensitive to disturbance.
Abundance very rare. Requires further surveying and research as this
species is a good example that could potentially be lost from the
Scottish flora.
Legislative
protection:
None
116
55.
Sphacelaria mirabilis
Common name:
Distribution:
Nothern species recorded on north
east coast of UK in Shetland, Fife and
Northumberland. Also occurs in
Norway, SW Sweden and the Gulf of
Maine.
Map shows likely current distribution
using the following information
sources:
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Intertidal rocks and pools; forms feathery crusts
Notes:
Germinates better at 12°C than at 4°C. Temperature and daylength
may limit distribution. Abundance: rare.
Legislative
protection:
None
117
56.
Dictyopteris membranacea
Common name:
Distribution:
Present from the Azores and Portugal
to the British Isles. A southern
species present in large amounts only
in the extreme south-west of Britain
with a few records from west
Scotland.
Map shows likely current distribution
using the following information
sources:
Norton, 1985; Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Notes:
Annual; there is a positive relationship between growth and temperature
(Friedlander and Ben-Amotz, 1990). Abundance: rare. Often dominant
in subtidal habitats in SW Britain but generally rarely encountered in
Scotland. An easily recognised species suitable for any studies of
distributional changes.
Legislative
protection:
None
118
57.
Taonia atomaria
Common name:
Distribution:
Southern species recorded from the
Azores to Ireland, England and the
Isle of Man. Very rare in Northern
Ireland and absent in Scotland.
Map shows likely current distribution
using the following information
sources:
I. Tittley (unpubl. data), Norton, 1985;
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Found in areas of sand scour
Notes:
Temperature and daylength may limit current distribution. Easily
recognisable species.
Legislative
protection:
None
119
58.
Carpomitra costata
Common name:
Distribution:
Southern species recorded in
Channel Islands and southern UK as
far north as the Isle of Man and
Donnegal. Rare in Ireland and only a
few records from the Outer Hebrides.
Map shows likely current distribution
using the following information
sources:
I. Tittley (unpubl. data), K. Hiscock
(unpubl. data), Picton & Costello,
1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Epilithic on bedrock and boulders; sublittoral to 37m; tolerant of sand
cover (Fletcher, 1987)
Notes:
Probably summer annual, recorded June to September (Fletcher,
1987). Good recognisable species to monitor.
Legislative
protection:
None
120
59.
Bifurcaria bifurcata
Common name:
Distribution:
Southern species recorded from
southern Spain to England and
Wales. Records from NW Ireland
require checking.
Map shows likely current distribution
using the following information
sources:
Crisp & Southward, unpubl. data; I.
Tittley (unpubl. data), Norton, 1985;
Picton & Costello, 1998; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Pool dwelling at northern limits of distribution; found on open rock at low
shore in Spain (Todd & Lewis, 1984)
Notes:
Intolerant of low air temperatures (Todd & Lewis, 1984). Absent from
Scotland. A rock pool species (in Britain) which is conspicous and
easily identified and would therefore provide a suitable species for
monitoring changes in distribution. Also forms low water zone in southwest England and west Ireland.
Legislative
protection:
None
121
60.
Ascophyllum nodosum mackaii
Common name:
A brown alga
Distribution:
Only recorded from Scotland in the
UK and in a few locations in Ireland.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
In variable or low salinity
Notes:
Scotland is the main European stronghold of this ecad of the much
more widely distributed Ascophylum nodosum, although significant
populations occur in Ireland. Habitat seems most important in
determining the development of this growth form but consideration
should be given to the effects of climate change. Occurs as
unattached balls.
Legislative
protection:
UK Biodiversity Action Plan: Species statement
122
61.
Fucus distichus distichus
Common name:
Distribution:
Northern species recorded from
Scotland to the Arctic. Not recorded
in Northern Ireland.
Map shows likely current distribution
using the following information
sources:
Powell, 1957; MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Tide pools on very exposed sites (Sideman & Mathieson, 1983;
Pearson & Brawley, 1996).
Notes:
Maximum growth winter and spring (Canada); repro Nov-May;mature at
2yrs; life span 2-3yrs; competes with Chondrus crispus; monoecious
(capable of self fertilization); avoids gamete release at high tide (when
water turbulent); zygotes remain unattached for at least one tidal cycle
(at the low temps recorded during repro season); daytime gamete
release (light required?) (Sideman & Mathieson, 1983; Pearson &
Brawley, 1996). Its occurrence on exposed sites means that locations
where it is found are isolated and may be difficult to access.
Nevertheless, a northern species, dedicated surveys should be
undertaken to establish a baseline of its current distribution.
Abundance: rare. Populations sporadic and restricted which may
indicate it is sensitive to disturbance.
Legislative
protection:
None
123
62.
Fucus evanescens
Common name:
Distribution:
Northern species recorded from
Denmark, Norway, Faroes, Iceland
and Shetland (only British record).
Map shows likely current distribution
using the following information
sources:
I. Tittley (unpubl. data), K. Hiscock
(unpubl. data)
Preferred habitat:
Mid-eulittoral to upper sublittoral at moderate to very sheltered sites
(Sideman & Mathieson, 1983)
Notes:
Maximum growth early summer (NW Atlantic); biomodal reproductive
period (spring/Autumn); mature at 2yrs; loss of tissue after reproduction;
life span 2-3yrs; competes with Chondrus crispus (Sideman &
Mathieson, 1983). Abundance: rare. This species has been widely
searched for in Scotland and the one record from Shetland (in Lerwick
Harbour) is considered to be a true record of its distribution.
Development of Lerwick Harbour may have adversely effected the
occurrence of this species which requires searching far and recording
as a baseline.
Legislative
protection:
None
124
63.
Codium adhaerens
Common name:
Distribution:
Southern species recorded from
Portugal/Mediterranean to British
Isles. Scottish records from
Inverness, Argyll and Mull. Rare in
Northern Ireland.
Map shows likely current distribution
using the following information
sources:
I. Tittley (unpubl. data), MERMAID
(www.jncc.gov.uk/mermaid)
Preferred habitat:
Lower littoral & sublittoral fringe; sheltered and exposed; low light and
strong flow of water (Burrows, 1991)
Notes:
Reproduces by biflagellate gametes; dioecious or occasionally
monoecious; probably more common than distribution; plants present
all year; fertile through summer; rarely fruit in some localities (Burrows,
1991). Abundance: rare on west coast only. Becoming more
widespread in Scotland.
Legislative
protection:
None
125
126
Appendix 6. Detailed information sheets for biotopes that are part of Biodiversity
Action Plans or that may change in distribution as a result of climate change.
Most of the information for the biotope sheets has been adapted from Connor et al.
(1997a,b) and MERMAID, www.jncc.gov.uk/mermaid. Species names follow Howson &
Picton (1997).
In the Natural Heritage Importance section, * = biotopes that may be consistently found
within the Habitats Directive Annex I type, ** = biotopes that are particularly characteristic of
the Habitats Directive Annex I type (i.e. restricted or almost restricted to that type).
127
128
1. Chthamalus spp. on exposed upper eulittoral rock
Biotope
Code:
ELR.MB.Bpat.Cht
Distribution:
Recorded on the west coast of Britain
as far north as Orkney.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Exposed to moderately exposed upper and mid eulittoral bedrock and boulders are characterised by
dense barnacles, Chthamalus spp. and the limpet Patella vulgata. On the west coast Chthamalus spp.
dominate the upper to mid eulittoral, often forming a distinct white band above a darker Semibalanus
balanoides zone (BPat.Sem). This is because Chthamalus montagui is better adapted to resist
desiccation and, therefore, extends further up the shore. There is much regional variation in the
distribution and zonation of Chthamalus spp. In more northern latitudes, such as north-west Scotland,
the abundance of Chthamalus is greater on more wave exposed shores. In the south-west Chthamalus
spp. can be the dominant barnacle throughout the eulittoral zone. Patches of Lichina pygmaea may be
prominent within the Chthamalus zone, especially in the south. Cracks and crevices in the rock provide
a refuge for small mussels Mytilus edulis, winkles Littorina saxatilis and the dogwhelk Nucella lapillus.
Damp crevices are also frequently occupied by red algae, particularly Osmundea pinnatifida and
encrusting coralline algae. With decreasing wave exposure Fucus vesiculosus is able to survive and
this alga gradually replaces the barnacles and Patella biotope (see FvesB). Chthamalus spp. are
uncommonly abundant in the upper eulittoral zone in very sheltered sealochs in Argyll, West Scotland.
Physical
environment:
On bedrock and large boulders on very exposed to moderately exposed
shores.
Main species:
Chthamalus montagui, Chthamalus stellatus, Patella vulgata,
Melarhaphe neritoides, Littorina neglecta & Mytilus edulis.
Likely change in
Overall appearance and functioning will be similar but component
relation to warming species of barnacles and limpets might change from predominantly
and notes:
northern (Semibalanus balanoides, Patella vulgata) to predominantly
southern (Patella ulyssiponensis, Chthamalus spp.) species. Monitoring
these species may provide an indication of more widespread change.
129
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Reefs *
Large shallow inlets and bays *
Estuaries *
130
2. Fucus distichus and Fucus spiralis f. nana on extremely exposed upper
shore rock
Biotope
Code:
ELR.FR.Fdis
Distribution:
Recorded on east Orkney. This
biotope is also thought to occur in
Shetland and St. Kilda
Map shows likely current distribution
using the following information
sources:
Powell, 1957; MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Extremely exposed gently or steeply sloping upper shore bedrock may support a mixture of Fucus
distichus and Fucus spiralis f. nana, the latter often at the top of the zone. This biotope is rare and
restricted to the far north and west coasts. This mixed band is generally found between the Verrucaria
maura and Porphyra zone (Ver.Por) above, and the Mytilus edulis and barnacle zone below (MytB).
Although it may occur above a red algal zone (Mas), as recorded on Barra or above a Porphyra and
sparse barnacle zone (Ver.Por) as on St Kilda.
Physical
environment:
Occurs on bedrock on extremely exposed shores.
Main species:
Melarhaphe neritoides, Littorina neglecta, Hildenbrandia rubra, Fucus
distichus, Fucus spiralis, Verrucaria maura & Verrucaria mucosa.
Likely change in
The northern species that characterise and give the biotope its name
relation to warming may decline in abundance and disappear from many shores so that the
and notes:
biotope will decline in abundance and extent in Scotland. Dedicated
searches have been undertaken for Fucus distichus but many locations
are isolated and difficult to access.
Natural heritage
importance
Part of Habitats Directive. Annex I Habitat:
Reefs *
131
3. Sabellaria alveolata reefs on sand-abraded eulittoral rock
Biotope
Code:
MLR.Sab.Salv
Distribution:
South and west coasts of England
and Wales and as far north as the
Solway Firth. There is also one
record on MERMAID from SE Uist.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Many wave-exposed boulder scar grounds in the eastern basin of the Irish Sea (and as far south as
Cornwall), are characterised by reefs of Sabellaria alveolata which build tubes from the mobile sand
surrounding the boulders and cobbles. The tubes formed by Sabellaria alveolata form large reef-like
hummocks, which serve to further stabilise the boulders. Other species in this biotope include the
barnacles Semibalanus balanoides, Balanus crenatus and Elminius modestus and the molluscs Patella
vulgata, Littorina littorea, Nucella lapillus and Mytilus edulis. Low abundances of algae tend to occur in
areas of eroded reef. The main algal species include Porphyra spp., Mastocarpus stellatus, Ceramium
spp., Fucus vesiculosus, Fucus serratus, Enteromorpha spp. and Ulva spp. On exposed surf beaches
in the south-west Sabellaria forms a crust on the rocks, rather than the classic honeycomb reef, and
may be accompanied by the barnacle Balanus perforatus (typically common to abundant). On waveexposed shores in Ireland, the brown alga Himanthalia elongata can also occur.
Physical
environment:
Found on cobbles, boulders, pebbles and sand on exposed to
moderately exposed open coasts.
Main species:
Sabellaria alveolata, Semibalanus balanoides, Balanus perforatus,
Elminius modestus, Littorina littorea, Nucella lapillus & Palmaria
palmata.
Likely change in
More extensive occurrence in suitable habitats in western Scotland is
relation to warming expected. The one record in south-east Uist should be checked
and notes:
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Reefs *
Large shallow inlets and bays *
Estuaries *
UK Habitat Action Plan: Sabellaria alveolata reefs
132
4. Ascophyllum nodosum ecad. mackii beds on extremely sheltered mid
eulittoral mixed substrata.
Biotope
Code:
SLR.FX.AscX.mac
Distribution:
Widely distributed in isolated
locations in sea lochs on the west
coast of Scotland. Possibly present in
Shetland (Brindister Voe).
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Beds of the free-living Ascophyllum nodosum ecad mackaii. Cobbles and other hard substrata are often
characterised by the normal form of Ascophyllum nodosum and other fucoids such as Fucus serratus
and Fucus vesiculosus. The loose mats of A. nodosum ecad mackaii provide a cryptic and humid
habitat for mobile species such as gammarids, the shore crab Carcinus maenas, littorinid molluscs
(especially Littorina littorea) and eels Anguilla anguilla. Semibalanus balanoides and Mytilus edulis are
commonly attached to pebbles and cobbles on the sediment, while the infauna may contain Arenicola
marina, Lanice conchilega and other polychaetes.
Physical
environment:
Extremely sheltered mid shore mixed substrata, usually subject to
variable salinity due to freshwater runoff.
Main species:
Littorina saxatilis, Littorina littorea, Anguilla anguilla, Ascophyllum
nodosum mackii.
Likely change in
This biotope is particularly important as the ecad. mackii is especially
relation to warming developed on the shores of Scottish sea lochs. However, the biotope is
and notes:
recorded from southern and south-west Ireland where temperatures are
higher than in Scotland at present. It seems likely that physical habitat
and low salinity conditions are most important in determining presence
of this biotope so that it is expected to continue to be present in
Scotland.
Legislative
protection:
Part of Habitats Directive Annex I Habitats:
Large shallow inlets and bays **
UK Habitat Action Plan: Ascophyllum nodosum mackii beds
133
5. Corallina officinalis and coralline crusts in shallow eulittoral rockpools.
Biotope
Code:
LR.Rkp.Cor
Distribution:
Present at open coast wave-exposed
locations all around the coast of
Scotland.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Shallow rockpools throughout the eulittoral zone may be characterised by a covering of encrusting
coralline algae on which Corallina officinalis often forms a dense turf. These 'coralline' pools have a
striking appearance as they are dominated predominantly by red algae. Filamentous and foliose red
algae found in these pools include Dumontia contorta, Mastocarpus stellatus and Ceramium rubrum.
The green algae Cladophora rupestris and Enteromorpha spp. can also occur. The pools may hold
large numbers of grazing molluscs, particularly Littorina littorea (which often occurs in exceptionally high
densities in upper shore pools), Patella vulgata and Gibbula cineraria. Gastropods may graze these
pools to such an extent that they are devoid of any foliose red algae, and are reduced to encrusting
coralline algae and large numbers of gastropods. Within the pools, pits and crevices are often occupied
by the anemone Actinia equina and small Mytilus edulis. In Ireland, the sea urchin Paracentrotus lividus
can dominate these shallow coralline pools (see Cor.Par). In south-west Britain, the brown alga
Bifurcaria bifurcata (Cor.Bif) or Cystoseira spp. (Cor.Cys) can be regionally dominant.
Physical
environment:
Moderate to high wave exposure and suitable rock structure to form
pools.
Main species:
Encrusting Corallinacea, Corallina officinalis.
Likely change in
The character of the various sub-biotopes is greatly dependent on the
relation to warming occurrence of southern species. There is therefore likely to be a shift
and notes:
towards sub-biotopes that include species such as the alga Cystoseira
tamariscifolia and an increase in the number of areas where the sea
urchin Paracentrotus lividus occurs. It may also be that increased
warming of pools together with continued spread via water currents will
lead to the presence of the non-native wireweed Sargassum muticum.
Legislative
protection:
Part of Habitats Directive Annex I Habitats:
Reefs *
134
6. Halichondria bowerbanki, Eudendrium arbusculum and Eucratea loricata
on reduced salinity tide-swept circalittoral mixed substrata
Biotope
Code:
ECR.BS.HbowEud
Distribution:
Recorded from the Clyde area sea
lochs only.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Circalittoral mixed substrata (bedrock, boulders, cobbles and pebbles) in reduced salinity conditions and
strong tidal streams. Halichondria bowerbanki, Mycale lobata, Eudendrium arbusculum and
Alcyonidium diaphanum are particularly characteristic of these conditions. This biotope is only known
from Loch Etive, a very impoverished low salinity version is present in the upper basin of Loch Etive.
Physical
environment:
Occurs on bedrock, boulders, cobbles and pebbles on very sheltered
shores.
Main species:
Halichondria bowerbanki, Eudendrium arbusculum, Balanus crenatus &
Ascidiella scabra.
Likely change in
Although restricted in occurrence to Scotland, it is not expected that
relation to warming warming will affect this biotope as component species are widely
and notes:
distributed in appropriate habitats.
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Reefs **
Large shallow inlets and bays **
UK Habitat Action Plan: Tidal rapids
135
7. Coralline crusts, Parasmittina trispinosa, Caryophyllia smithii, Haliclona
viscosa, polyclinids and sparse Corynactis viridis on very exposed
circalittoral rock.
Biotope
Code:
ECR.Efa.CCParCar
Distribution:
Present in exposed or very waveexposed habitats at scatted locations
along the west coast and in Shetland.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Sparse Corynactis viridis, encrusting bryozoans and coralline algae on clean, often deep circalittoral
rock. The fauna is often sparse and has the appearance of being grazed but may also be effected by
violent wave action working into deep water during winter storms. Other species include large
specimens of the sponge Haliclona viscosa, the bryozoan Parasmittina, the sea cucumber Holothuria
forskali, the cup coral Caryophyllia and sparse hydroids such as Schizotricha frutescens and Nemertesia
antennina. This biotope also contains polyclinid ascidians. There appears to be a northern
(Shetland/Orkney) variant of this biotope which is virtually devoid of sponges, whilst Caryophyllia is less
common than in the south and west and grazing by Echinus seems to have a marked effect.
Physical
environment:
Occurs on bedrock and large stable boulders and cobbles at exposed
and very wave-exposed locations.
Main species:
Alcyonium digitatum, Caryophyllia smithii, Corynactis viridis,
Parasmittina trispinosa, Porella compressa, encrusting Corallinacea.
Likely change in
This is one of several circalittoral open coast biotopes that occasionally
relation to warming include southern species. The abundance and occurrence of species
and notes:
such as the jewel anemone Corynactis viridis, the sea cucumber
Holothuria forskali, the ross Pentapora fascialis (=Pentapora foliacea)
and, in less exposed situations, red sea fingers Alcyonium glomertum
and zoanthid anemone Parazoanthus axinellae is likely to increase as a
result of increased temperatures.
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Reefs **
136
8. Erect sponges and Swiftia pallida on slightly tide-swept moderately
exposed circalittoral rock
Biotope
Code:
MCR.Xfa. ErSSwi
Distribution:
Present in appropriate wavesheltered habitats along the west
coast and along the east coast of the
Outer Hebrides.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Circalittoral rock subject to slight tidal currents, with the seafan Swiftia pallida and various erect
branching and cup sponges, including Axinella infundibuliformis, Stelligera spp. and Raspailia spp. The
rocky surfaces usually have a sparse turf of hydroids including Aglaophenia tubulifera and Schizotricha
frutescens, bryozoans Bugula spp., Caryophyllia smithii, Porella compressa and occasionally Alcyonium
glomeratum and Diazona violacea. The feather stars Antedon bifida and Antedon petasus (the latter
more numerous in deeper water than the former) and large solitary ascidians Ascidia mentula and
Polycarpa pomaria (see AmenCio) are also characteristic of the less exposed sites with this biotope.
Rock surfaces often with Neocrania anomala - found both in Irish and Scottish examples of this biotope.
Short verticals and overhangs occasionally with Parazoanthus anguicomus. Mycale lingua recorded in
deep water at some of the sites in Scottish sealochs. There are a few records from Kenmare River in
SW Ireland which have Swiftia and Eunicella at the same sites. These records have been included in
ErSEun although there were several other biotopes in Kenmare River which share close links with those
from Scottish sealochs.
Physical
environment:
Occurs on bedrock, stable boulders and cobbles on exposed to
moderately exposed shores.
Main species:
Alcyonium glomeratum, Swiftia pallida, Caryophyllia smithii,
Parasmittina trispinosa, Porella compressa, Antedon bifida, Antedon
petasus, encrusting Corallinacea.
137
Likely change in
Probable loss of the sea fan Swiftia pallida, and addition in inshore
relation to warming areas of southern species such as the zoanthid anemone Parazoanthus
and notes:
axinellae, ross Pentapora foliacea and the yellow branching sponge
Axinella dissimilis together with the possible addition the Scottish fauna
of the southern sea fan Eunicella verrucosa would most likely change
this biotope to the ‘southern form’: MCR.Xfa.erSEun (erect sponges,
Eunicella verrucosa and Pentapora foliacea on slightly tide-swept
moderately exposed circalittoral rock).
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Reefs **
Large shallow inlets and bays *
138
9. Modiolus modiolus beds with hydroids and red seaweeds on tide-swept
circalittoral mixed substrata
Biotope
Code:
MCR.M.ModT
Distribution:
Recorded off west Scotland,
Shetland, Orkney and NW Wales.
Map shows likely current distribution
using the following information
sources:
A.J. Southward, unpubl. data;
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Modiolus beds on mixed substrata (cobbles, pebbles and coarse muddy sediments) in moderately
strong currents, typically on the open coast but also in tide-swept channels of marine inlets. Often with
sponges such as Hemimycale columella, hydroids such as Sertularia argentea, Hydrallmania falcata and
Abietinaria abietina, Alcyonium digitatum, barnacles, Alcyonium digitatum, bryozoans such as
Alcyonidium mytili and ascidians Dendrodoa grossularia. This biotope is typified by examples off the
north-west Lleyn Peninsula in N Wales and off Co. Down, Northern Ireland.
Physical
environment:
Occurs on cobbles, pebbles and Modiolus shells on moderately
exposed to sheltered shores.
Main species:
Modiolus modiolus, Sertularia argentea, Alcyonium digitatum,
Pomatoceros triqueter, Balanus crenatus, Hyas araneus, Electra pilosa,
Corallinaceae & Phycodrys rubens
Likely change in
This biotope is the one most typically found in Scotland. It includes a
relation to warming rich variety of species associated with clumps of horse mussels.
and notes:
However, Modiolus biotopes do occur further south than Scotland
suggesting that a significant rise in temperature would be required to
adversely affect the presence of Modiolus as a key structuring species.
Overall, there may be some decline in locations of marginal suitability
for this biotope.
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Reefs **
Large shallow inlets and bays **
UK Habitat Action Plan: Modiolus modiolus beds
139
10. Sheltered Modiolus (horse-mussel) beds
Biotope
Code:
SCR.Mod
Distribution:
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Circalittoral mixed substrata, not influenced by significant tidal currents, with clumps or more extensive
beds of Modiolus modiolus. ModHAs typically occurs in sealochs and the Shetland voes. Large solitary
ascidians (Ascidiella aspersa, Corella parallelogramma, Ciona intestinalis) and fine hydroids
(Bougainvillia ramosa, Kirchenpaueria pinnata) present attached to the mussel shells. Decapods such
as spider crabs and Munida rugosa typically present. Aequipecten opercularis often present. The much
richer version of this biotope ModCvar has far more sponges and hydroids growing on and amongst the
Modiolus and large numbers of Chlamys varia. Brittlestars Ophiothrix fragilis and Ophiocomina nigra, as
well as Ophiopholis aculeata are often common, sometimes forming a dense bed as described in Oph.
The biotope ModHo, characterised by Modiolus and holothurians occurs in similar physiographic
features, although seems to be in softer sediment in some cases.
Physical
environment:
Mixed substrata on sheltered to very sheltered shores.
Main species:
ModHAs: Modiolus modiolus, Aequipecten opercularis, Corallinaceae,
Munida rugosa, Pomatoceros triqueter & Terebellidae.
ModCvar: Cerianthus lloydii, Urticina felina, Pomatoceros triqueter,
Balanus balanus, Pagurus bernhardus, Gibbula cineraria,
Pleurobranchus membranaceus, Modiolus modiolus, Chlamys varia,
Aequipecten opercularis, Asterias rubens, Ophiothrix fragilis,
Psammechinus miliaris, Echinus esculentus, Ciona intestinalis, Corella
parallelogramma & Ascidiella aspersa.
140
Likely change in
This biotope is the one most typically found in Scotland. It includes a
relation to warming rich variety of species associated with clumps of horse mussels.
and notes:
However, Modiolus biotopes do occur further south than Scotland
suggesting that a significant rise in temperature would be required to
adversely affect the presence of Modiolus as a key structuring species.
Overall, there may be some decline in locations of marginal suitability
for this biotope and of the several species associated with the biotope
that appear to be more abundant in Scotland including Balanus
balanus, Chlamys varia, Aequipected opercularis and Psammechinus
miliaris.
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Reefs **
Large shallow inlets and bays **
UK Habitat Action Plan: Modiolus modiolus beds
141
11. Phymatolithon calcareum maerl beds in infralittoral clean gravel or coarse
sand
Biotope
Code:
IGS.Mrl.Phy
Distribution:
Recorded off NW Scotland, Orkney
and Shetland.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Maerl beds characterised by Phymatolithon calcareum in gravels and sands. Associated epiphytes
include red algae such as Cryptopleura ramosa, Brongniartella byssoides and Plocamium cartilagineum
with Desmarestia spp. and Dictyota dichotoma also very often present. Algal species may be anchored
to the maerl or to dead bivalve shells amongst the maerl. Polychaetes, such as Chaetopterus
variopedatus, and the gastropods Gibbula magus and Gibbula cineraria may be present. Liocarcinus
depurator and Liocarcinus corrugatus are often present, although they may be under-recorded; it would
seem likely that robust infaunal bivalves such as Circomphalus casina, Mya truncata and Dosinia
exoleta are more widespread than available data currently suggests. At some sites where IGS.Phy
occurs, there may be significant patches of maerl gravel containing the rare burrowing anemone
Halcampoides elongatus; this may be a separate biotope, but insufficient data exists at present.
Northern maerl beds in the UK do not appear to contain L. corallioides but in south-west England and
Ireland L. corallioides may occur to some extent in IGS.Mrl.Phy as well as IMX.Lcor, where it dominates.
In IGS.Mrl.Phy.Hec hydroids present are typically erect colonies such as Nemertesia spp. and often
occur on the maerl or attached to dead shells within the maerl. Echinoderms such as Antedon bifida,
Ophiothrix fragilis, Ophiocomina nigra, Ophiura albida and Neopentadactyla mixta are occasional or
frequent in Phy.HEc but do not often occur in Phy.R.
Physical
environment:
Maerl gravel and course sand on moderately exposed shores.
Main species:
Phymatolithon calcareum, Lithothamnion corallioides, Neopentadactyla
mixta, Cerianthus lloydii & Plocamium cartilagineum.
Likely change in
This is the type of maerl bed found in full salinity conditions in Scotland.
relation to warming
and notes:
142
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Sandbanks which are slightly covered by sea water all the time **
Large shallow inlets and bays *
Lagoons *
Habitats Directive Annex V
UK Habitat Action Plan: Maerl beds
143
12. Lithothamnion glaciale maerl beds in tide-swept variable salinity
infralittoral gravel
Biotope
Code:
IGS.Mrl.Lgla
Distribution:
Northern biotope with southern limit
at Lundy. Recorded in west Scotland
and Shetland.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Upper infralittoral tide-swept channels of coarse sediment subject to variable or reduced salinity which
support distinctive beds of Lithothamnion glaciale maerl 'rhodoliths'. Phymatolithon calcareum may also
be present as a more minor maerl component. This biotope can often be found at the upper end of
Scottish sealochs where the variable salinity of the habitat may not be immediately obvious. Associated
fauna and flora may include species found in other types of maerl beds (and elsewhere), e.g.
Chaetopterus variopedatus, Lanice conchilega, Mya truncata, Plocamium cartilagineum and Phycodrys
rubens. Lgla, however, also has a fauna that reflects the slightly reduced salinity conditions, e.g.
Psammechinus miliaris is often present in high numbers along with other grazers such as chitons and
Tectura spp. Hyas araneus, Ophiothrix fragilis and Henricia oculata are also fairly typically present at
sites. In Scottish lagoons (obs) this biotope may show considerable variation but the community falls
within the broad description defined here.
Physical
environment:
Maerl; shell gravel; stones and coarse sediment on sheltered to
extremely sheltered shores.
Main species:
Lithothamnion glaciale, Laminaria saccharina, Phymatolithon
calcareum, Psammechinus miliaris, Ophiothrix fragilis, Mya truncata,
Tectura virginea & Cerianthus lloydii.
144
Likely change in
Lithothamnion glaciale is widespread and often abundant in the Arctic
relation to warming region and reaches its southern limit of distribution in Britain (Yorkshire,
and notes:
Lundy) and Ireland (Galway, Down). The distinctive beds of maerl
‘rhodoliths’ that occur in Scotland are the most likely maerl beds to be
adversely affected by sea water temperature warming. However it
seems likely that warming would need to be substantial (2ºC or more)
for significant change to occur in the maerl. Some componants of the
biotope such as Tectura testudinalis may be lost and the maerl bed
might beome dominated by Phymatolihon calcareum, already a
component of the biotope.
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Sandbanks which are slightly covered by sea water all the time *
Large shallow inlets and bays **
Lagoons *
UK Habitat Action Plan: Maerl beds
145
13. Lithothamnion corallioides maerl beds on infralittoral muddy gravel
Biotope
Code:
IMX.MrlMx.Lcor
Distribution:
Recorded in SW Ireland and UK.
Scottish records are unconfirmed due
to problems with identification.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Live maerl beds in sheltered, silty conditions which are dominated by Lithothamnion corallioides with a
variety of foliose and filamentous seaweeds. Live maerl is at least common but there may be noticeable
amounts of dead maerl gravel and pebbles. Other species of maerl, such as Phymatolithon calcareum
and Phymatolithon purpureum, may also occur as a less abundant component. Species of seaweed
such as Dictyota dichotoma, Halarachnion ligulatum, Gracilaria verrucosa and Ulva spp. are often
present, although are not restricted to this biotope, whereas Dudresnaya verticillata and Cutleria
multifida tend not to occur on other types of maerl beds. The anemones Anthopleura ballii, Anemonia
viridis and Cereus pedunculatus and the fan worm Myxicola infundibulum are typically found in Lcor
whereas Echinus esculentus tends to occur more in other types of maerl. Lcor has a south-western
distribution in Britain and Ireland. Sheltered, stable, fully saline maerl beds in the north of Great Britain
(where L. corallioides has not been confirmed to occur) may need to be described as an analogous
biotope to Lcor (see Phy).
Physical
environment:
Muddy maerl gravel on sheltered to very sheltered shores.
Main species:
Lithothamnion corallioides, Phymatolithon calcareum, Dictyota
dichotoma, Dudresnaya verticillata & Tectura virginea.
Likely change in
Many of the species in this biotope are southern in distribution.
relation to warming
and notes:
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Sandbanks which are slightly covered by sea water all the time **
Large shallow inlets and bays **
Habitats Directive Annex V
UK Habitat Action Plan: Maerl beds
146
14. Halcampa chrysanthellum and Edwardsia timida on sublittoral clean stone
gravel
Biotope
Code:
IGS.FaG.HalEdw
Distribution:
Recorded in west Scotland in Loch
Creran, Loch Eynort (Skye) and
Church Bay (Rathlin Island). Also
occurs in Strangford Narrows.
Map shows likely current distribution
using the following information
sources:
MERMAID (www.jncc.co.uk/mermaid)
Description:
Periodically (seasonally?) disturbed sublittoral stone gravel with small pebbles characterised by the
presence of the anemones Halcampa chrysanthellum and Edwardsia timida. This biotope may also be
contain opportunistic red seaweeds such as Palmaria palmata, Associated species are often typical of a
hydroid/bryozoan turf but with infauna such as Sabella pavonina and Megalomma vesiculosum. It
should be noted that this habitat may show considerable variation in community composition.
Physical
environment:
On clean stone gravel with pebbles on moderately exposed to sheltered
shores
Main species:
Edwardsia timida & Halcampa chrysanthellum.
Likely change in
relation to warming
and notes:
Legislative
protection:
Part of Habitats Directive. Annex I Habitat:
Large shallow inlets and bays *
UK Habitat Action Plan: Sublittoral sands and gravels
147
15. Ruppia maritima in reduced salinity infralittoral muddy sand
Biotope
Code:
IMS.Sgr.Rup
Distribution:
Recorded off west Scotland
(especially the Outer Hebrides),
Shetland, Orkney and the Moray
Firth.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
In sheltered brackish muddy sand and mud, beds of Ruppia maritima and more rarely Ruppia spiralis
may occur. These beds may be populated by fish such as Gasterosteus aculeatus and Spinachia
spinachia which are less common on filamentous algal-dominated sediments. Seaweeds such as
Chaetomorpha spp., Enteromorpha spp., and Chorda filum are also often present. In some cases the
stoneworts Chara aspera and Lamprothamnium papulosum occur. Although only recorded from
Scotland in the searches undertaken for this study, it is likely the biotope occurs in the Fleet in Dorset,
England.
Physical
environment:
Occurs on muddy fine sand to mud on extremely sheltered shores.
Main species:
Ruppia maritima, Ruppia spiralis, Lamprothamnium papulosum,
Filamentous green algae, Mysidae
Likely change in
Lamprothamnium papulosum is a red list species.
relation to warming
and notes:
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Sandbanks which are slightly covered by sea water all the time **
Estuaries *
Lagoons **
UK Habitat Action Plan: Seagrass beds
148
16. Serpula vermicularis reefs on very sheltered circalittoral muddy sand
Biotope
Code:
CMS.Ser
Distribution:
Reefs only recorded from Loch
Creran and Loch Sween on west
coast of Scotland. Reefs in the latter
are now reported to be dead.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Large clumps (mini 'reefs') of the calcareous tubes of Serpula vermicularis, typically attached to stones
on muddy sediment in very sheltered conditions in sealochs. A rich associated biota attached to the
calcareous tube may include Esperiopsis fucorum, thin encrusting sponges, the ascidians Ascidiella
aspersa, Pyura microcosmus and Diplosoma listerianum and fine hydroids such as Halopteris catharina.
In shallow water dense Phycodrys rubens may grow on the 'reefs'. Reefs from Loch Creran have been
recently studied. The only other known site in UK for these reefs is Loch Sween, where they are
reported to have deteriorated. Otherwise only known from Salt Lake, Cliffden and Killary Harbour, Co.
Galway.
Physical
environment:
Occurs on calcareous tubes, pebbles and shells on sediment on very
sheltered to extremely sheltered shores.
Main species:
Kirchenpaueria pinnata, Eupolymnia nebulosa, Myxicola infundibulum,
Pomatoceros triqueter, Serpula vermicularis, Pandalus montagui,
Psammechinus miliaris, Diplosoma listerianum, Corella
parallelogramma, Ascidiellaspersa, Dendrodoa grossularia, Pyura
microcosmus, Corallinaceae & Phycodrys rubens.
Likely change in
A rich habitat which is included because of its importance.
relation to warming
and notes:
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Reefs **
Large shallow inlets and bays **
UK Habitat Action Plan: Serpulid reefs
149
17. Seapens, including Funiculina quadrangularis, and burrowing megafauna
in undisturbed circalittoral soft mud
Biotope
Code:
CMU.SpMeg.Fun
Distribution:
Recorded in Scottish west coast sea
lochs.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Deep muds, especially in sealochs, which support populations of seapens such as Virgularia mirabilis
and Pennatula phosphorea, but sometimes also with forests of the nationally scarce Funiculina
quadrangularis. The sediment is usually extensively burrowed by crustaceans, the most common of
which is Nephrops norvegicus, but Callianassa subterranea may also be present (the latter is likely to be
under-recorded by grab sampling because it is deep burrowing). Lesueurigobius friesii is present at
many sites. Amphiura spp. are usually present in high densities
Physical
environment:
On mud on sheltered to very sheltered shores.
Main species:
Funiculina quadrangularis, Pennatula phosphorea, Nephrops
norvegicus, Turritella communis & Amphiura filiformis.
Likely change in
This is a Scottish biotope where Scotland holds the major European
relation to warming resource and requires assessment of any impact of climate change.
and notes:
Legislative
protection:
Part of Habitats Directive. Annex I Habitat:
Large shallow inlets and bays *
UK Habitat Action Plan: Mud habitats in deep waters
150
18. Beggiatoa spp. on anoxic sublittoral mud
Biotope
Code:
CMU.Beg
Distribution:
Recorded in Scottish west coast sea
lochs.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Sublittoral soft anoxic mud, often in areas with poor water exchange with the open sea, can have a
conspicuous bacterial mat covering of Beggiatoa spp. The anoxia may be a result of natural conditions
of poor water exchange in some sealochs (and many Scandinavian fjords) or artificially under fish farm
cages from nutrient enrichment. The fauna is normally impoverished at such sites, with few elements of
the infaunal communities present in other muddy biotopes. Scavenging species such as Asterias
rubens and Carcinus maenas are typically present where the habitat is not too anoxic but in extreme
conditions of anoxia little survives other than the Beggiatoa. The polychaete Ophiodromus flexuosus
occurs in high densities at the interface between oxygenated and deoxygenated sediments (in
Norwegian fjords).
Physical
environment:
On mud on very sheltered to extremely sheltered shores.
Main species:
Beggiatoa spp.
Likely change in
This biotope is included as anoxia can occur as a result of thermal
relation to warming stratification (which may increase as a result of warming).
and notes:
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Large shallow inlets and bays *
Lagoons *
UK Habitat Action Plan: Mud habitats in deep water
151
19. Sabellaria spinulosa and Polydora spp. on stable circalittoral mixed
sediment
Biotope
Code:
CMX.SspiMx
Distribution:
Reefs recorded off the east coast of
England, just extending north into
Scotland.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
The tube-building polychaete Sabellaria spinulosa at high abundances on mixed sediment, with
Polydora spp. tubes attached. Infauna comprise typical sublittoral polychaete species, together with the
bivalves Abra alba and Nucula nitidosa. Epifauna comprise calcareous tubeworms, pycnogonids, hermit
crabs and amphipods.
Physical
environment:
Occurs on mixed sediments on moderately exposed shores.
Main species:
Tubulanus, Nematoda, Polynoidae, Pholoe, Phyllodocidae, Eteone,
Glycera, Glycinde nordmanni, Syllis, Exogone naidina, Exogone
verugera, Nephtys, Lumbrineris gracilis, Prionospio, Spiophanes
bombyx, Cirratulidae, Mediomastus fragilis, Scalibregma inflatum,
Sabellaria spinulosa, Ampharetidae, Abra alba, Sphenia binghami,
Ophiura spp.
Likely change in
relation to warming
and notes:
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Reefs **
Large shallow inlets and bays *
Estuaries *
UK Habitat Action Plan: Sabellaria spinulosa reefs
152
20. Modiolus modiolus beds on circalittoral mixed sediment
Biotope
Code:
CMX.ModMx
Distribution:
Recorded off the Shetland, Orkney,
west Scotland, Wales and east
England.
Map shows likely current distribution
using the following information
sources:
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Muddy gravels and coarse sands in deeper water of continental seas may contain venerid bivalves with
beds of Modiolus modiolus. The clumping of the byssus threads of the M. modiolus creates a stable
habitat that attracts a very rich infaunal community. Brittlestars such as Ophiothrix fragilis may also
occur with this community. This biotope is very similar to the 'boreal off-shore gravel association' and
the 'deep Venus community' described by previous workers (Ford 1923; Jones 1951). Similar Modiolus
beds on open coast stable boulders, cobbles and sediment are described under MCR.ModT.
Physical
environment:
Occurs on muddy gravel and sand, with shells and stones on
moderately exposed to sheltered shores.
Main species:
Modiolus modiolus, Buccinum undatum & Ophiothrix fragilis
Likely change in
relation to warming
and notes:
Legislative
protection:
Part of Habitats Directive. Annex I Habitats:
Reefs **
Large shallow inlets and bays *
Estuaries *
UK Habitat Action Plan: Modiolus modiolus beds
153
21. Sparse Modiolus modiolus, dense Cerianthus lloydii and burrowing
holothurians on sheltered circalittoral stones and mixed sediment
Biotope
Code:
CMX.ModHo
Distribution:
Recorded off west Scotland and
Shetland.
Map shows likely current distribution
using the following information
sources:
A.J. Southward, unpubl. data;
MERMAID
(www.jncc.gov.uk/mermaid)
Description:
Pebbles and cobbles on muddy shell gravel in sealochs with dense Cerianthus lloydii and sparse
Modiolus modiolus. Large burrowing holothurians (many only extend their tentacles above the sediment
surface seasonally) include Psolus phantapus, Paracucumaria hyndmani, Thyonidium commune,
Thyone fusus and Leptopentacta elongata. This biotope is well developed in the Clyde sealochs,
although many examples are rather species-poor. Some examples in south-west Scotland sealochs
have greater quantities of boulders and cobbles and therefore have a richer associated biota (compared
with other sheltered Modiolus bed biotopes such as ModHAs). Examples in Shetland are somewhat
different in having the cucumber Cucumaria frondosa amongst sparse Modiolus beds and a slightly
different balance in abundance of other species; for example the brittlestar Ophiopholis aculeata is more
abundant in these far northern examples in the voes and narrows (see Oph.Oacu).
Physical
environment:
Occurs on pebbles, boulders and cobbles on muddy gravel on
sheltered to very sheltered shores.
Main species:
Modiolus modiolus, Cerianthus lloydii, Pagurus bernhardus, Ophiura
albida & Psolus phantapus.
Likely change in
relation to warming
and notes:
Legislative
protection:
Part of Habitats Directive. Annex I Habitat:
Large shallow inlets and bays **
UK Habitat Action Plan: Modiolus modiolus beds
154
Appendix 7. Predictions of climate change (temperature rise) for selected
representative species.
The species names used in the following information sheets are those used in The Species
Directory of the Marine Fauna and Flora of the British Isles and Surrounding Seas (Howson
& Picton, 1997) where authorities for species names can be found. Pentapora fascialis
(Pallas) is considered (Hayward & Ryland 1999) to include Pentapora foliacea, the name
used in the Species Directory.
1.
Swiftia pallida ............................................................................................................ 157
2.
Eunicella verrucosa................................................................................................... 159
3.
Anemonia viridis........................................................................................................ 161
4.
Phellia gausapata...................................................................................................... 163
5.
Chthamalus montagui ............................................................................................... 165
6.
Chthamalus stellatus................................................................................................. 167
7.
Lithodes maia............................................................................................................ 169
8.
Maja squinado........................................................................................................... 171
9.
Gibbula umbilicalis .................................................................................................... 173
10.
Osilinus lineatus (=Monodonta lineata) ...................................................................... 175
11.
Patella depressa ........................................................................................................ 178
12.
Tectura testudinalis .................................................................................................... 180
13.
Pentapora fascialis (=Pentapora foliacea) ................................................................. 182
14.
Paracentrotus lividus.................................................................................................. 184
15.
Strongylocentrotus droebachiensis ............................................................................ 186
16.
Holothuria forskali ...................................................................................................... 188
17.
Cucumaria frondosa................................................................................................... 190
18.
Lithothamnion glaciale ............................................................................................... 192
19.
Odonthalia dentata..................................................................................................... 194
20.
Dictyopteris membranacea ........................................................................................ 196
21.
Codium adhaerens..................................................................................................... 198
22.
Bifurcaria bifurcata ..................................................................................................... 200
23.
Fucus distichus distichus ........................................................................................... 202
155
156
1. Swiftia pallida
Image: Swiftia pallida at Ardnoe Point.
Image width c. 25 cm.
Unknown / JNCC
Common name: Northern sea-fan
Current
Only recorded in west Scotland and
distribution: St Kilda in Great Britain.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Swiftia pallida will become less abundant and, with a 2ºC rise in summer seawater
temperatures, will no longer occur on the mainland coast although there will be a lag period of
20+ years after temperatures reach 2ºC higher.
Climate change type: Type B, Northern stables
Expected change in distribution: Remain in areas where it is currently Frequent (Firth of
Lorne to Skye on the mainland and St Kilda) (1ºC) or cease to be present in Scotland except
for St Kilda (2ºC).
Explanation: Swiftia pallida is a cold water / deep water species with probably lecithotrophic
short-lived larvae recruiting locally. Reproductive ‘triggers’ may be cold or warm temperatures
and, if winter low temperature is important, decline in relation to rising temperatures may be
slower than now predicted on the basis of summer temperatures. The fact that it occurs in
157
quite high densities in some locations suggests that it is currently not at the limits of it’s
geographical range as affected by temperatures. Furthermore, the presence of a population of
Swiftia only, apparently, in the Kenmare River in Ireland (Picton & Costello 1998) suggests
that the species typically has a very localised distribution but is self-sustaining even in a part of
the British Isles where summer (although possibly not winter) temperatures are typically
warmer than in Scotland. The species is probably quite long lived (over 10 years) and existing
colonies will persist even if temperature rise makes reproductive viability lower. Therefore,
where quite high densities occur, the species would be expected to persist, although in
declining density, for more than 20 years after a critically high temperature is reached.
Expected rate of change in distribution: Retreat in distribution is likely to be slow (unlikely
to be revealed for 20 years + after a change in temperature).
Explanation: Sea fans usually grow slowly and once established are unlikely to be adversely
affected by higher temperatures and so persist but not be replaced by new stock.
Expected change in abundance or population structure at locations where the species
already occurs: Significant decrease in abundance expected.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: The apparent absence of Swiftia from Shetland suggests that geographical
barriers have prevented colonization and therefore a self-sustaining population. Those
geographical barriers will continue to prevent colonization in Shetland even in a situation of
retreat.
Species that might be displaced by increased abundance of this species: None.
Effects on biotopes: Biotope MCR.ErSSwi (Erect sponges and Swiftia pallida on slightly tideswept moderately exposed circalittoral rock) remains the same but characterizing species
change and the biotope might become closer to MCR.ErSEun (Erect sponges Eunicella
verrucosa and Pentapora foliacea on slightly tide-swept moderately exposed circalittoral rock).
Suggested monitoring: Recording scheme by volunteer divers guided to locations. Part of a
programme searching for a small range of easily identified species. Care will need to be taken
in separating Eunicella verrucosa (which is white and sparsely branching in Irish examples)
from Swiftia pallida.
References:
Picton, B.E. & Costello, M.J. (1998). The BioMar biotope viewer: a guide to marine habitats,
fauna and flora in Britain and Ireland. Dublin: Environmental Sciences Unit, Trinity College.
(CD-ROM)
158
2. Eunicella verrucosa
Image: Colonies of pink and of white
forms of Eunicella verrucosa
at Lundy. Image width c. 50
cm. Keith Hiscock.
Common name: Pink sea fan
Current
A southern species recorded as far
distribution: north as NW Ireland and SW Wales.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Eunicella verrucosa will become more abundant where it currently exists and
should spread slowly along the Northern Irish coast. If the species extends across the
significant geographical barrier of the North Channel, it will spread only slowly and would not
be expected to start to colonise areas indicated in Scotland for 30 years+ after a 2ºC rise in
summer seawater temperatures.
Climate change type: Type E, Southern stables.
Expected change in distribution: Occurrence in Scotland not expected (1ºC) or extension to
the mainland of western Scotland (2ºC).
Explanation: Eunicella verrucosa is a boreal-lusitanean species most likely with a short-lived
lecithotrophic larva. However, it does colonise new surfaces such as wrecks remote from
rocky areas and so has the ability to spread. The maximum northerly extent of distribution
159
appears to correspond approximately to the 14ºC summer isotherm. Its distribution is
therefore likely to extend northwards in the Irish Sea from its current recorded northern limit in
north Pembrokeshire eventually reaching the Lleyn Peninsula and west Anglesey. However,
the extensive sedimentary areas of the east basin of the Irish Sea may prove too much of a
barrier even if many larvae are being produced. Recruitment from Northern Ireland is more
likely than through the Irish Sea although large numbers of larvae will need to be produced
and favourable currents occur so that the crossing is made successfully.
Expected rate of change in distribution: Expansion in distribution is likely to be very slow
(unlikely to be revealed for 30 years + after a change in temperature).
Explanation: It is most likely that the larvae of Eunicella verrucosa are short lived and will be
produced infrequently and in small numbers at the edge of range. Colonies are slow growing
(c. 1 cm in branch length per annum) and it is unknown at what size they become
reproductively viable but expected to be a few years after settlement. It might require several
years in which large numbers of larvae are produced and a favourable current occurs for the
establishment of a viable population in Scotland to build-up.
Expected change in abundance or population structure at locations where the species
already occurs: Not present currently in Scotland.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: It might require several years in which large numbers of larvae are
produced and a favourable current occurs for the establishment of a viable population in
Scotland to build-up. Geographical barriers will continue to prevent colonisation in Shetland
even in a situation of expansion.
Species that might be displaced by increased abundance of this species: None.
Effects on biotopes: Biotope MCR.ErSSwi (Erect sponges and Swiftia pallida on slightly tideswept moderately exposed circalittoral rock) may ‘evolve’ into MCR.ErSEun (Erect sponges
Eunicella verrucosa and Pentapora foliacea on slightly tide-swept moderately exposed
circalittoral rock).
Suggested monitoring: Recording scheme by volunteer divers guided to locations. Part of a
programme searching for a small range of easily identified species. Care will need to be taken
in separating Eunicella verrucosa (which is white and sparsely branching in Irish examples)
from Swiftia pallida.
References:
160
3. Anemonia viridis
Image: The green form of Anemonia
viridis. Rum Bay, Plymouth.
Image width c. 10 cm. Keith
Hiscock
Common name: Snakelocks
anemone
Current
A southern species recorded as far
distribution: north as Orkney. Absent from
Shetland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Gradual extension and increase in abundance around the coast of mainland
Scotland, the Hebrides and in Orkney but unlikely to extend to Shetland.
Climate change type: Type F, Southern gradual extenders.
Expected change in distribution: Spread north and east to about Duncansby Head (1ºC) or
Berwick (2ºC).
Explanation: Distribution appears to be determined by temperature. Increase in air and
seawater temperatures, including milder conditions in winter, will enable/allow spread
Expected rate of change in distribution: Sporadic but moderately rapid. Could extend 10 to
50 km in one year but only under favourable conditions. Overall extension likely to be slow
with changes/new locations observed only several years after change in temperature.
Explanation: Planulae larvae are lecithotropic but most likely remain in the plankton for
several days (J.Turner, pers. comm.) and could therefore increase extent by probably more
161
than 10 but less than 50 km in one year following successful breeding. Adults may also
release from the seabed and allow themselves to be carried by currents but probably not a
great distance. Populations that were apparently destroyed during the 1962-63 cold winter
had “only recently become re-established” (Manual, 1981) indicating that recruitment from
unaffected areas occurred quite slowly.
Expected change in abundance or population structure at locations where the species
already occurs: Increase (through longitudinal fission and sexual reproduction but also
because of reduction in the mortality that most likely occurs in cold winters at the limit of
distribution).
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Local warming of rockpools in which the species is found may increase
prospects for production of gametes and accelerate expansion of extent. Larvae may be swept
offshore at locations such as Cape Wrath and may not ‘turn the corner’ to colonise the north
and east coasts. The distance between Orkney and Shetland including Fair Isle might be too
great for the fairly short-lived lecithotropic larvae to make the jump.
Species that might be displaced by increased abundance of this species: None.
Effects on biotopes: Anemonia viridis is found in coralline rockpools (LR.Cor) although is
only specifically noted as characterising in LR.Rkp.Cor.Par which has the sea urchin
Paracentrotus lividus and is only identified from southwest Ireland. Nevertheless, Anemonia is
likely to be an addition to coralline rockpool biotopes and to damp lower shore situations
without adverse effects on other species there. Similarly, Anemonia is frequently found
attached to seagrass Zostera marina (IMS.Zmar) where it is an addition to the diversity of this
biotope.
Suggested monitoring: Recording scheme by volunteers guided to locations. Part of a
programme searching for a small range of easily identified species.
References:
Manual, R.L. (1981). British Anthozoa. London: Academic Press.
162
4. Phellia gausapata
Image: Phellia gausapata at Rockall.
Image width c. 8 cm. David Connor
/ JNCC
Common name:
Current
A northern species recorded in west
distribution: Scotland, Shetland and Northern
Ireland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Phellia gausapata is likely to become less abundant and, with a 2ºC rise in
summer seawater temperatures, will no longer occur on the mainland coast although there will
be a lag period of many decades after temperatures reach 2ºC higher.
Climate change type: Type B, Northern stables
Expected change in distribution: Decline and eventual retreat. At 1ºC increase, may be lost
from less wave exposed locations and, at 2ºC from mainland Scotland and Orkney but not for
several decades after new temperatures are reached.
Explanation: Phellia gausapata is a cold water species that reproduces asexually by basal
laceration (Manual, 1981). No information has been found on the triggers for asexual or likely
sexual reproduction or for any lethal temperature limits. Once established, the anemones are
likely to be more tolerant of change in maximum or minimum temperatures than are important
for reproduction. Because of the predominantly asexual reproduction and the usually long163
lived nature of sea anemones, any adverse effects of increased temperature are therefore
likely to be revealed only slowly. Where quite high densities occur, the species would be
expected to persist, although in gradually declining density, for more than several decades
after a critically high temperature adversely affecting reproduction is reached. It may also be
that the southern jewel anemone Corynactis viridis, which lives in similar habitats, may outcompete for space with Phellia gausapata as temperature conditions favour more southern
species.
Expected rate of change in distribution: Retreat in distribution is likely to be slow (unlikely
to be revealed for 20 years + after a change in temperature).
Explanation: Phellia gausapata is most likely, as in other anemones, long-lived. Established
populations may persist for some time and continue to reproduce asexually.
Expected change in abundance or population structure at locations where the species
already occurs: Decline.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: None.
Species that might be displaced by increased abundance of this species: Not relevant.
Effects on biotopes: Phellia gausapata is a characterising species in EIR.KfaR.AlaAnSC
(Alaria esculenta forest with dense anemones and sponge crusts on extremely exposed
infralittoral bedrock) which is recorded only at Rockall. Otherwise, it occurs especially in wave
exposed biotopes on vertical or steeply sloping rock including those in EIR.SG (Robust faunal
cushions and crusts). Other anemones, especially the widely distributed Sagartia elegans,
may increase in abundance if Phellia declined and the jewel anemone Corynactis viridis, a
southern species, take over space vacated by Phellia.
Suggested monitoring: Recording scheme by volunteer divers guided to locations. Part of a
programme searching for a small range of easily identified species.
References:
Manual, R.L. (1981). British Anthozoa. London: Academic Press.
164
5. Chthamalus montagui
Image: Cthamalus montagui. Image
width c. 12 mm. Alan
Southward.
Common name: Montagu’s punctate
barnacle
Current
A southern species recorded as far
distribution: north as Orkney. Rare on the east
coast of Scotland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Annual
recruitment
Occasional
recruitment
Not breeding
Summary: Abundance and occurrence will increase within the current geographical range of
the species. Distributional range will extend down the east coast. Expansion of range will
closely follow increase in summer temperatures.
Climate change type: F to G, Southern extender.
Expected change in distribution: Increased occurrence and abundance along the northern
and western coasts; extension of range down the eastern coast. Replacement of
Semibalanus balanoides as the dominant barnacle in the upper mid eulittoral.
Explanation: Higher summer temperatures, both air and seawater, will result in more regular
and prolonged release of planktonic larvae at existing locations. There may also be additional
broods. The larvae remain in the plankton for several weeks so the potential to extend is high.
However, development to a settling stage may not occur if the larvae are swept into too cold
waters so extension is not measured by distance travelled.
165
Expected rate of change in distribution: Expansion of range will closely follow increase in
summer temperatures.
Explanation: Chthamalus montagui larvae develop in response to temperature and are
capable of distribution beyond limits on development imposed by cold temperatures so that
temperature rather than dispersal ability will determine rate of extension.
Expected change in abundance or population structure at locations where the species
already occurs: Expansion of dominance in the upper and mid eulittoral subzones will occur
closely following increase in summer temperatures.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Spread to Shetland is strongly dependant on the direction of residual
currents (which generally sweep eastwards past the north of Orkney). There may not be
sufficient longevity of the planktonic stage to reach Shetland although Fair Isle may act as a
‘staging post’.
Species that might be displaced by increased abundance of this species: Semibalanus
balanoides is likely to be displaced in the upper and mid eulittoral at locations where the
abundance of Chthamalus montagui increases.
Effects on biotopes: ELR.Bpat (Barnacles and Patella spp. on exposed or moderately
exposed, or vertical sheltered, eulittoral rock) is characterised by Semibalanus balanoides in
the north at present but Chthamalus spp. in the south-west. Chthamalus montagui will
become more abundant and displace Semibalanus balanoides but the biotope will remain the
same. Because Chthamalus montagui is better able to resist dessication than Semibalanus
balanoides, the barnacle zone will extend further up the shore.
Suggested monitoring: Recording annually at selected stations by specialist marine
biologists or trained volunteers.
References:
Crisp, D.J., Southward, A.J., & Southward, E.C. (1981). On the distribution of the intertidal
barnacles, Chthamalus stellatus, Chthamalus montagui and Euraphia depressa. Journal of
the Marine Biological Association of the United Kingdom, 61, 359-380.
166
6. Chthamalus stellatus
Image: Cthamalus stellatus. Image
width c. 10 mm. Alan
Southward.
Common name: Poli’s stellate
barnacle
Current
A southern species recorded as far
distribution: north as Shetland, but rare on the
east coast of Scotland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Annual
recruitment
Occasional
recruitment
Not breeding
Summary: Abundance and occurrence will increase within the current geographical range of
the species. Distributional range will extend down the east coast. Expansion of range will
closely follow increase in summer temperatures.
Climate change type: F to G, Southern extender.
Expected change in distribution: Increased occurrence and abundance along the northern
and western coasts; extension of range down the eastern coast. Replacement of
Semibalanus balanoides as the dominant barnacle in the lower midlittoral especially on wave
exposed shores.
Explanation: Higher summer temperatures, both air and seawater, will result in more regular
and prolonged release of planktonic larvae at existing locations. There will also be additional
broods (Burrows et al. 1992). The larvae remain in the plankton for several weeks so the
potential to extend is high. However, development to a settling stage may not occur if the
167
larvae are swept into too cold waters so extension is not measured by distance travelled.
Expected rate of change in distribution: Expansion of range will closely follow increase in
summer temperatures.
Explanation: [AJS to check and change] Chthamalus stellatus larvae develop in response
to temperature and are capable of distribution beyond limits on development imposed by cold
temperatures so that temperature rather than dispersal ability will determine rate of extension.
Chthamalus stellatus has greater dispersive powers than Chthamalus montagui (Burrows
1988; Pannacuilli et al. 1996) and range extension of breeding populations could occur faster
than for Chthamalus montagui.
Expected change in abundance or population structure at locations where the species
already occurs: Expansion of dominance in the mid eulittoral subzone will occur closely
following increase in summer temperatures. The higher abundance will be most evident in
wave-exposed sites.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Larval distribution may be over dispersed on eastern coasts and settlement
inhibited by scarcity of exposed rocky shores.
Species that might be displaced by increased abundance of this species: Semibalanus
balanoides is likely to be displaced in the lower half of the mid eulittoral at locations where the
abundance of Chthamalus stellatus increases.
Effects on biotopes: ELR.Bpat (Barnacles and Patella spp. on exposed or moderately
exposed, or vertical sheltered, eulittoral rock) is characterised by Semibalanus balanoides in
the north at present but Chthamalus spp. in the south-west. Chthamalus stellatus will become
more abundant and displace Semibalanus balanoides especially on exposed coasts but the
biotope will remain the same.
Suggested monitoring: Recording annually at selected stations by specialist marine
biologists. Photographic sampling and examination of images by professsional marine
biologists.
References:
Crisp, D.J., Southward, A.J., & Southward, E.C. (1981). On the distribution of the intertidal
barnacles, Chthamalus stellatus, Chthamalus montagui and Euraphia depressa. Journal of
the Marine Biological Association of the United Kingdom, 61, 359-380.
Southward, A.J. (1976). On the taxonomic status and distribution of Chthamalus stellatus in
the north-east Atlantic region. Journal of the Marine Biological Association of the United
Kingdom, 56, 1007-1028.
168
7. Lithodes maia
Image: Lithodes maia. Image width c. 40
cm. Sue Scott / JNCC
Common name: Northern stone crab
Current
A northern species recorded in west
distribution: Scotland and Shetland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Decline in abundance and loss after a few years from areas of temperature
increase.
Climate change type: Type C, Northern retreaters
Expected change in distribution: Retreat northwards to about Cape Wrath (1ºC) or cease to
be present in Scottish inshore waters (2ºC).
Explanation: Lithodes maia occurs in inshore areas most likely as an outlier of deeper water
populations. The current recorded distribution seems to be restricted to areas where summer
surface temperatures inshore do not rise above 14ºC including one record as far south as
between the Isle of Man and the Mull of Galloway (Bruce, Colman & Jones, 1963). The
surface water temperature appears of importance to larval development with development
poor at 12ºC compared to 9ºC (Anger, 1996). Larvae spend about three months in surface
waters (www.qc.dfo.ca/iml/en/ress/cr-epin – cited on 12 April 2000). Larval survival is
therefore likely to be affected by warming sea surface temperatures.
169
Expected rate of change in distribution: Retreat in distribution slow. Possibly with a ten to
20 year lag after temperature reaches defined levels.
Explanation: Adults are likely to survive and remain in the same areas but will eventually die
and not be replaced.
Expected change in abundance or population structure at locations where the species
already occurs: Significant decrease in abundance expected.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: It is not known if the species has a lethal temperature for adults that is
within the range of temperatures predicted.
Species that might be displaced by increased abundance of this species: None.
Effects on biotopes: None detectable.
Suggested monitoring: Recording scheme by volunteer divers guided to locations. Part of a
programme searching for a small range of easily identified species. Care will need to be taken
in ensuring that Maja squinado is not mistaken for Lithodes maia (photographic evidence of
significant finds required).
References:
Bruce, J.R., Colman, J.S. & Jones, N.S. (1963). Marine Fauna of the Isle of Man. Liverpool
University Press.
Anger, K. (1996). Physiological and biochemical changes during lecithotrophic larval
development and early juvenile growth in the northern stone crab, Lithodes maja (Decapoda:
Anomura). Marine Biology 126, 283-296.
170
8. Maja squinado
Image: Maja squinado with carapace
covered in barnacles. North
Devon. Image width c. 30 cm.
Keith Hiscock
Common name: Thorn back spider
crab
Current
A southern species recorded as far
distribution: north as the Isle of Man and NW
Ireland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Annual
recruitment
Occasional
recruitment
Not breeding
Summary: Maja squinado is likely to spread to Scottish waters and increase in abundance
and distribution although only on the west coast with increase in summer temperatures
.
Climate change type: Southern rapid extenders.
Expected change in distribution: Spread northwards on the west coast to about Mull (1ºC)
or Skye and to the outer Hebrides (2ºC).
Explanation: Maja squinado has a planktonic larva that most likely lives for several weeks
thus providing the ‘opportunity’ to make the journey from Northern Ireland to Scotland.
However, larvae are present in the plankton only during September and October in the
northern Irish Sea (Williamson, 1956) compared to July to September in the Plymouth area
(Lebour, 1926) suggesting that prospects for production of larvae are best in warmer waters.
Larval survival and progression through all stages to settlement is most likely within the period
of the primary productive season if temperatures are sufficiently high (Lindley, 1998).
171
Expected rate of change in distribution: Small numbers should start to appear in southwest Scotland a few years after summer temperatures have regularly reached higher levels.
However, recruitment will be from distant breeding stocks with only a slight (1ºC) rise in
temperature. Once temperatures reach 2ºC higher than at present, more frequent recruitment
can be expected from distant breeding stocks and Scottish stocks may begin to breed at which
point numbers are likely to increase and spread rapidly and in accordance with rising seawater
temperatures.
Explanation: Spread to Scotland will be dependant on suitable currents carrying larvae to
Scotland. Suitable conditions may occur only every few years but the crabs live for several
years and so do not require regular recruitment to establish a population. Suitable habitats for
settlement are widespread in Scotland. However, breeding from Scottish stocks is only likely
after temperatures reach a suitable level, probably at the 2ºC increase.
Expected change in abundance or population structure at locations where the species
already occurs: Not relevant to Scotland.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Spread to Scotland is dependant of water currents carrying larvae to
suitable habitats.
Species that might be displaced by increased abundance of this species: None.
Effects on biotopes: Maja squinado does not characterise any particular biotopes and is
widely distributed usually in small numbers in shallow rock and sediment biotopes. Occurrence
in Scotland will not alter occurrence of any biotopes.
Suggested monitoring: Recording scheme by volunteer divers guided to locations. Part of a
programme searching for a small range of easily identified species. Care will need to be taken
in ensuring that Lithodes maia is not mistaken for Maja squinado.
References:
Lebour, M.V. (1926). Studies of the Plymouth Brachyura. I. The rearing of crabs in captivity
with a description of the larval stages of Inachus dorsettensis, Macropodia longirostris and
Maia squinado. Journal of the Marine Biological Association of the United Kingdom, 14, 795821.
Lindley, J.A. (1998). Diversity, biomass and production of decapod crustacean larvae in a
changing environment. Invertebrate Reproduction and Development, 33, 209-219.
Williamson, D.I. (1956). The plankton of the Irish Sea. Bulletin of Marine Ecology, 3, 87-114.
172
9. Gibbula umbilicalis
Image: Gibbula umbilicalis top and
underside view showing
smooth round aperture.
Whitsand Bay, South
Cornwall. Image width c. 4 cm.
Keith Hiscock.
Common name: Flat top shell
Current
A southern species recorded as far
distribution: north as Orkney. Rarely recorded on
the east coast of Scotland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Annual
recruitment
Occasional
recruitment
Not breeding
Summary: Gibbula umbilicalis will extend its distribution to the north and east coasts of
Scotland and will increase in its abundance in suitable habitats where it already occurs. It is
unlikely to spread to Shetland because of the distance between Orkney and Shetland and the
improbability that Fair Isle would be a ‘staging post’.
Climate change type: Type G, Southern rapid extenders.
Expected change in distribution: Abundance and occurrence will increase within the current
geographical range of the species. Distributional range will extend down the east coast.
However, the species might not spread to Shetland.
Explanation: There are suitable habitats present along the eats coast of Scotland and so
spread is expected. However, prosobranch veligers may not extend far offshore (Fretter &
Shale 1973 found very low numbers only 6 km offshore of Plymouth compared with inshore).
173
Colonisation of Shetland would only occur if suitably strong currents in the right direction
occurred at the right time to colonise. Fair Isle is not considered as a ‘staging post’ as suitable
(sufficiently sheltered) habitats are too few to support populations that would produce large
numbers of larvae.
Expected rate of change in distribution: Expansion of range will closely follow increase in
summer temperatures.
Explanation: There are extensive suitable habitats on in eastern Scotland. Larvae are long
lived and so will recruit inshore and the population will build.
Expected change in abundance or population structure at locations where the species
already occurs: Abundance will increase and the structure of the population will become
more even between year classes.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Geographical barriers – areas of open sea may restrict extension of range.
Species that might be displaced by increased abundance of this species: None.
Effects on biotopes: Gibbula umbilicalis is a characterising species of the MLR.BF
(Barnacles and fucoids on moderately exposed shores) biotopes and of MLR.R.Osm
(Osmundea (Laurencia) pinnatifida and Gelidium pusillum on moderately exposed mid
eulittoral rock). However, it is widely distributed (but not characterising) in other biotopes
together with other prosobranchs. Whilst it might compete for food resources with other
grazing molluscs, it is not expected that any biotopes would be changed in type by its
occurrence.
Suggested monitoring: Recording scheme by specialist marine biologists or trained
volunteers guided to locations. Sites on the north and east coast of Scotland should be
especially targeted for presence. Abundance should be monitored in Orkney. Part of a
programme of searching for a small range of easily identified species by volunteers. However,
samples will be required to confirm identification.
References:
Fretter, V. & Shale, D. (1973). Seasonal changes in population density and vertical
distribution of prosobranch veligers in offshore plankton at Plymouth. Journal of the Marine
Biological Association of the United Kingdom, 53, 471-492.
174
10.
Osilinus lineatus (=Monodonta lineata)
Image: Osilinus lineatus top view and
underside showing ‘tooth’.
South Devon. Image width c. 2
cm (left); 1.2cm (right). Keith
Hiscock
Common name: Toothed topshell
Current
A southern species recorded as far
distribution: north as Anglesey and Northern
Ireland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Annual
recruitment
Occasional
recruitment
Not breeding
Summary: Larvae may not reach south-west Scotland and may not extend to offshore islands.
There may be occurences in south-west Scotland following a rise in air and sea temperatures
of 1ºC. Those occurences are likely to be none-breeding and sparse. Increased production of
larvae from sources outside of Scotland and the capability of Scottish populations to breed
after temperatures have risen by about 2ºC, should enable the species to expand its
distribution and abundance sporadically according to incidence of favourable conditions for
breeding and distribution, eventually extending to much of the west coast and possibly The
Hebrides.
Climate change type: Type F, Southern gradual extenders.
Expected change in distribution: May not reach Scotland or offshore islands in Scotland. If it
reaches Scotland, spread northwards on the west coast to about Mull (1ºC) or Skye (2ºC).
Explanation: Prosobranch veligers may not extend far offshore (Fretter & Shale 1973 found
175
very low numbers only 6 km offshore of Plymouth compared with inshore). Hawkins & Hiscock
(1983) found few Osilinus on Lundy, 11 km from the nearest mainland, and suggested poor
larval dispersal and that Lundy-produced larvae would be swept away and not colonise the
island. It may take a significant period of suitably strong currents in the right direction at the
right time to colonise the Scottish coast. The suggested change in distribution assumes that
air and seawater temperature is important for breeding and the survival of larvae. However,
Kendall, Williamson & Garwood (1987) dispute that particularly warm conditions are required
for Monodonta lineata to develop its gonads or to spawn. Near the northern limits of
distribution in west Wales, they found that cold winters may adversely affect survival of settled
individuals. It seems likely that a variety of factors including distance from existing populations
(geographical barriers), seawater temperature and air temperature are important in
determining current absence from Scotland. Also, populations might need to build and the
species does not appear to be very long-lived (two and a half years in Brittany according to
Daguzan 1991). Once established in Scotland, there are widespread suitable habitats and the
species should extend in accordance with change in temperature represented by summer
seawater.
Expected rate of change in distribution: Fairly rapid once a breeding population is
established on the south-west Scottish coast.
Explanation: Once established and breeding is successful, there are extensive suitable
habitats on the south-west and west coast of Scotland. Larvae will recruit inshore and the
population will build.
Expected change in abundance or population structure at locations where the species
already occurs: Increase (following colonisation). Irregular size structure, missing year
classes and a bias towards older animals is predicted by Lewis et al. (1982) in edge-of-range
populations.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Geographical boundaries to larval distribution (see above).
Species that might be displaced by increased abundance of this species: Additional
grazing of fucoid algae and therefore reduction in abundance may occur.
Effects on biotopes: No mention has been found of Osilinus in the biotopes classification
although it can be the dominant species on some sheltered very bare upper shore rocks
especially where shallow pools occur. It may be that additional grazing by Osilinus will reduce
abundance of fucoids in SLR.F.Fspi (Fucus spiralis on moderately exposed to very sheltered
upper eulittoral rock) and in SLR.F.Fves (Fucus vesiculosus on sheltered mid eulittoral rock).
Suggested monitoring: Recording scheme by specialist marine biologists or trained
volunteers guided to locations. Sites on the Mull of Kintyre and Islay may be particularly
targetted. Part of a programme of searching for a small range of easily identified species by
volunteers. However, samples will be required to confirm identification.
References:
Daguzan, J. (1991). Research on growth and ecology of Monodonta lineata (daCosta)
(Gastropoda, Prosobranchia, Trochidae) living on the Atlantic coast of Brittany. Cahiers de
Biologie Marine, 32, 3-22.
Fretter, V. & Shale, D. (1973). Seasonal changes in population density and vertical
distribution of prosobranch veligers in offshore plankton at Plymouth. Journal of the Marine
Biological Association of the United Kingdom, 53, 471-492.
Hawkins, S.J. & Hiscock, K. (1983). Anomalies in the abundance of common eulittoral
176
gastropods with planktonic larvae on Lundy Island, Bristol Channel. Journal of Molluscan
Studies, 49, 86-88.
Kendall, M.A., Williamson, P. & Garwood, P.R. (1987). Annual variation in recruitment and
population structure of Monodonta lineata and Gibbula umbilicalis populations at Aberaeron,
mid-Wales. Estuarine & Coastal Marine Science, 24, 499-511.
Lewis, J., Bowman, R.S., Kendall, M.A. & Williamson, P. (1982). Some geographical
components in population dynamics: possibilities and realities in some littoral species.
Netherlands Journal of Sea Research, 16, 18-28.
Turk, S.M., & Seaward, D.R. (1997). The marine fauna of the Isles of Scilly - Mollusca.
Journal of Natural History, 31, 555-633.
177
11.
Patella depressa
Image: Patella depressa line drawing.
Shell length c. 2 cm. From:
Hawkins & Jones (1992)
Common name: Black-footed limpet
Current
A southern species which reaches its
distribution: northern limits on Anglesey.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Annual
recruitment
Occasional
recruitment
Not breeding
Summary: May not extend to Scotland even following significant warming. Spread is likely to
be slow and unlikely to be beyond south-west Scotland if it occurs.
Climate change type: Type F, Southern gradual extenders.
Expected change in distribution: May not spread to Scotland. Would probably not reach
Scotland following a 1ºC rise but may spread as far as Islay and Jura and into the Firth of Lorn
on a 2ºC rise.
Explanation: Patella depressa failed to establish in Ireland after the last ice age whilst
spreading along the English and Welsh coasts as far as Anglesey in the north and the Isle of
Wight in the east. Neither has it colonised the Isle of Man although transplant experiments
have shown that it can survive and reach maturity there (S.J. Hawkins, unpublished). Powers
of dispersal may therefore prevent spread to Scotland across significant geographical barriers.
If the sea barriers are crossed, it should thrive on the Irish coast and the Isle of Man and
eventually in Scotland.
178
Expected change in abundance or population structure at locations where the species
already occurs: Occasionally recruiting or non-recruiting populations will recruit annually.
Irregular size structure, missing year classes and a bias towards older animals is predicted by
Lewis et al. (1982) in edge-of-range populations. (Such changes would occur outside of
Scotland, on Anglesey and the Lleyn Peninsula.)
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Patella depressa does not seem to disperse as well as Patella vulgata and
Patella ulyssiponensis. For instance, it is not common on Lundy (Hawkins & Hiscock 1983),
nor in the Isles of Scilly (Crisp & Southward 1958). It has failed to reach Ireland. Should it do
so, Ireland would be the most likely path to Scotland although an alternative route exists via
the Isle of Man or Cumbria where suitable habitats are further apart.
Species that might be displaced by increased abundance of this species: The balance
between numbers of Patella depressa and Patella vulgata changes with climate change
(Southward et al. 1995). Increases in Patella depressa would result in decreases in Patella
vulgata.
Effects on biotopes: Fucoid-barnacle biotopes may become less dominated by fucoids. In
areas where Patella depressa increases, there is less likelihood of ‘Fucus escapes’ and the
dynamic patchiness typical of the middle of moderately exposed shores. This will be because
Patella depressa does not aggregate under clumps of Fucus in the same way as Patella
vulgata (Roberts, Hawkins & Thompson, unpublished observations). Grazing pressure should
also be more stable with the two species recruiting at different times of the year.
Suggested monitoring: Stratified random sampling of the proportion of Patella depressa to
Patella vulgata on seaward-facing, well-drained midshore rock on moderately exposed shores
at key locations. Timed searches at edge of range locations recording abundance using
appropriate scales. Key locations are Northern Ireland, Isle of Man, Cumbria, Galloway, Islay.
References:
Crisp, D.J. & Southward, A.J. (1958). The distribution of intertidal organisms along the coasts
of the English Channel. Journal of the Marine Biological Association of the United Kingdom,
37, 157-208.
Hawkins, S.J. & Hiscock, K. (1983). Anomalies in the abundance of common eulittoral
gastropods with planktonic larvae on Lundy Island, Bristol Channel. Journal of Molluscan
Studies, 49, 86-88.
Hawkins, S.J. & Jones, H.D. (1992). Marine Field course guide. 1, Rocky shores. London,
IMMEL Publishing.
Lewis, J., Bowman, R.S., Kendall, M.A. & Williamson, P. (1982). Some geographical
components in population dynamics: possibilities and realities in some littoral species.
Netherlands Journal of Sea Research, 16, 18-28.
Southward, A.J., Hawkins, S.J. & Burrows, M.T. (1995). 70 years observations of change in
distribution and abundance of zooplankton and intertidal organisms in the western EnglishChannel in relation to rise in sea temperature. Journal of Thermal Biology, 20, 127-155.
Southward, A.J. & Crisp, D.J. (1954). The distribution of certain intertidal animals around the
Irish coast. Proceedings of the Royal Irish Academy, 57(B), 1-29.
179
12.
Tectura testudinalis
Image: Tectura testudinalis on lower
shore rocks at Millport. Image
width c. 3 cm. Keith Hiscock.
Common name: Tortoiseshell limpet
Current
distribution:
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Annual
breeding
Occasional
breeding
Not breeding
Summary: Tectura testudinalis (=Tectura tessulata) is a circumpolar species currently
reaching its southern limit in the north of England and Ireland but expected to retreat
northwards in parallel with increases in temperature.
Climate change type: Type C, Northern retreaters.
Expected change in distribution: Decline or disappearance from Northern Ireland, the Isle of
Man, Cumbria and only occasionally recruiting populations being found in southern Scotland.
(In recent years, Tectura testudinalis has become much rarer in Northern Ireland (J. Nunn,
pers.comm.) and in the Isle of Man (S. Hawkins, own observations).
Expected rate of change in distribution: Evidence from the Isle of Man a nd Northern
Ireland suggests that retreat could be rapid – in line with changes in temperature.
Expected change in abundance or population structure at locations where the species
180
already occurs: Infrequent recruitment will lead to less dense populations dominated by fewer
older individuals. Such a change has already occurred in Northern Ireland at least.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Since residual current flows are against the direction that recruitment
would occur from larvae of distant populations, the truncation of distribution may occur rapidly.
Although little is known about the distributional abilities of larvae of Tectura testudinalis, they
are likely to be limited as in other archaeogastropods.
Species that might be displaced by increased abundance of this species: Not relevant.
(Decreased abundance might allow more algal growth on the lower shore although it is most
likely that other limpets will increase abundance. Tectura virginea may increase in abundance
but occurs in slightly different habitats – deeper especially on stones and shells).
Effects on biotopes: Tectura testudinalis is not named as a characterising species in any
infralittoral biotopes. Acmaeid limpets have been shown to be strongly associated with
crustose corallines (on north American coasts, they are associated especially with
Clathromorphum circumscriptum: Sterech, 1992). Reduction in grazing from Tectura
testudinalis may lead to crustose corallines being overgrown. However, since garzing is
undertaken by several limpet and chiton species it is more likely that there will be not change
in the presence of biotopes at locations.
Suggested monitoring: Timed searches by specialist marine biologists or trained volunteers /
quadrat counts at suitable locations. Part of a programme of searching for a small range of
easily identified species by volunteers. However, samples will be required to confirm
identification.
References:
Stenech, R.S. (1992). Plant-herbivore co-evolution: the fossil record. In Plant-animal
interactions in the marine benthos (eds. D.M. John, S.J. Hawkins & J.H. Price). Oxford
University Press, Oxford. (Systematics Association Special Volume No. 46).
181
13.
Pentapora fascialis (=Pentapora foliacea∗)
Image: A small colony of Pentapora
fascialis. Lundy. Image width
c. 20 cm. Keith Hiscock.
Common name: Ross
Current
Widely distributed in south-west
distribution: Britain and western Ireland with
sporadic records from the west coast
of Scotland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Likely to increase in abundance and extent at current locations to become more
widely distributed in those locations and, following a 2ºC rise in temperature, may become
generally distributed on the west coast of Scotland.
Climate change type: Type E, southern stables.
Expected change in distribution: Likely to become more widespread in the areas where it
currently occurs following a 1ºC rise in seawater temperature and present in suitable habitats
all along the west coast of Scotland following a 2ºC rise in temperature.
∗
A recent classification (Hayward and Ryland, 1999) includes Pentapora foliacea within
Pentapora fascialis in the family Bitectiporidae.
182
Explanation: Reproduction is most likely temperature dependant and so larvae will be
produced more frequently and/or in larger numbers. However, the larvae are lecithotropic and
so are unlikely to spend a long time in the plankton to spread to distant locations.
Expected rate of change in distribution: Change will occur slowly and it is likely to be
several decades at least even following a significant (2ºC) rise in temperature before the
species might be considered widely distributed on the west coast of Scotland.
Explanation: The larvae are lecithotropic and so are unlikely to spend a long time in the
plankton to spread to distant locations. However, it does colonise new surfaces such as
wrecks remote from rocky areas and so has the ability to spread.
Expected change in abundance or population structure at locations where the species
already occurs: Increase.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Pentapora fascialis appears, in its present distribution, to favour open coast
areas in Scotland. It is likely that there will be some incursion to tidal sounds but not into
enclosed sea lochs where habitats are unsuitable for a passive suspension feeder because of
lack of water movement.
Species that might be displaced by increased abundance of this species: None.
Effects on biotopes: Pentapora fascialis is a characteristic species in several circalittoral
biotopes although is named only in the title of MCR.ErSEun (Erect sponges, Eunicella
verrucosa and Pentapora foliacea on slightly tide-swept moderately exposed circalittoral rock).
This is the biotope which it is suggested might develop in Scotland following significant
seawater temperature rise.
Suggested monitoring: Recording scheme by volunteer divers guided to locations. Part of a
programme searching for a small range of easily identified species.
References:
Hayward, P.J. & Ryland, J.S., (1999). Cheilostomatous Bryozoa. Part II Hippothooidea Celleporoidea. Synopses of the British Fauna (New Series), (ed. D.M. Kermack & R.S.K.
Barnes), The Linnean Society of London. London: Academic Press. [Synopses of the British
Fauna, no. 14. 2nd edition.]
183
14.
Paracentrotus lividus
Image: Paracentrotus lividus (centre)
sharing a tidepool in Duntulm
Bay, northern Skye with two
Psammechinus miliaris.
September 1971. Image width
c. 12 cm. Alan Southward.
Common name: Purple sea urchin
Current
A southern species recorded as far
distribution: north as Skye. Rarely recorded in
west Scotland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Annual
recruitment
Occasional
recruitment
Not breeding
Climate change type: Type F, Southern gradual extender.
Expected change in distribution: Occurring more widely in areas where it is currently found
but is very localised. Extension of range to(wards) the north coast of Scotland.
Explanation: Production of larvae occurs in spring and early summer in both the
Mediterranean (Lopez et al. 1998) and Brittany (Spirlet, Grosjean & Jangoux 1998). The latter
authors report that the rate of gametogenesis and the end of the spawning period is influenced
by temperature whilst the first spawning event appears to be triggered by daylength.
Therefore, a rise in temperature should favour reproduction further north than at present.
Expected rate of change in distribution: Sporadic but moderately rapid. Overall extension
likely to be slow with changes/new locations observed only several years after change in
temperature.
184
Explanation: Very large numbers of long-lived larvae are produced of which a significant
number (12.7% in the study by Lopez et al. 1998) may survive to settlement. However, it may
take a combination of a year when larval production is good and currents are favourable in
speed and direction for larvae to be taken to western Scotland from Ireland. Suitable new
habitats may not be available on most of the west coast of Scotland. Paracentrotus occurs in
greatest numbers on limestone rock although may also be attracted by thick coralline crusts.
Expected change in abundance or population structure at locations where the species
already occurs: Likely to be more frequent at suitable sites from Islay, through the inner
islands, to Skye.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Paracentrotus lividus has complex habitat requirements including clean
rocky shore pools with wave action or clean sub-littoral shell gravel with less wave action. The
species occurs in the intertidal in rockpools on calcareous (soft) substrata and may be
particularly extensive where there are large numbers of such pools. However, encrusting
coralline algae provide such substrata and rock type does not necessarily need to be
limestone or chalk.
Species that might be displaced by increased abundance of this species: Paracentrotus
lividus grazes on algae and may create rockpools dominated by robust encrusting calcareous
algae with erect foliose species no longer present or present in abundance.
Effects on biotopes: The biotope LR.Rkp.Cor (Corallina officinalis and coralline crusts in
shallow eulittoral rockpools) will become LR.Rkp.Cor.Par (Coralline crusts and Paracentrotus
lividus in shallow eulittoral rockpools) where Paracentrotus colonises. However, other species
are characteristic of LR.Rkp.Cor.Par including species of Codium and Cladophora especially
and a ‘switch’ from the biotope to sub-biotope may not be complete. Where Paracentrotus
colonises shallow sublittoral areas in enclosed water bodies, the likely change in biotope is
unclear but a one similar to that present in very shallow water in Lough Hyne in south-west
Ireland (Kitching, 1987) (and probably close to LR.Rkp.Cor.Par) may develop in some Scottish
sealochs.
Suggested monitoring: Recording scheme by specialist marine biologists or trained
volunteers guided to locations. Sites on Skye may be particularly targetted. Part of a
programme of searching for a small range of easily identified species by volunteers. However,
samples will be required to confirm identification.
References:
Kitching, J.A. (1987). Ecological studies at Lough Hyne. Advances in Ecological Research,
17, 115-186.
Lopez, S., Turon, X., Montero, E., Palacin, C., Duarte, C.M. & Tarjuelo, I. (1998). Larval
abundance, recruitmenta and early mortality in Paracentrotus lividus (Echinoidea). Interannual
variability and plankton-benthos coupling. Marine Ecology Progress Series, 172, 239-251.
185
15.
Strongylocentrotus droebachiensis
Image: Strongylocentrotus
droebachiensis. Shetland.
Image width c. 40 cm. Sue
Scott / JNCC
Common name: Green sea urchin
Current
A northern species recorded in
distribution: Shetland and confined to the east
coast of Britain.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Strongylocentrotus droebachiensis will most likely persist in Shetland if seawater
temperatures rise by 1ºC but recruitment and survival may cease leading to loss from Scotland
following a 2ºC rise in temperature.
Climate change type: Type B, Northern stables.
Expected change in distribution: No significant change expected (1ºC) but may cease to be
present in Scotland (2ºC).
Explanation: Strongylocentrotus droebachiensis has a long lived (~2.5 months) planktotrophic
larva (Thorson, 1946). This species is unlikely to reproduce in Shetland as embryos (which
are produced in early spring) have an upper temperature limit of 8ºC (Strathmann, 1987). The
current records of this species on the east coast of Shetland are probably not from a selfrecruiting population and may rely on larval input from elsewhere (e.g. Norway). It may be that
populations in the relevant part of Norway may cease to produce larvae or significant numbers
186
of larvae because of seawater warming there.
Expected rate of change in distribution: Retreat in distribution relatively slow.
Explanation: This species is relatively long lived (at least 10 years) (Meidel & Scheibling,
1998a) and a lethal upper temperature limit for adults will not be reached within current
predictions.
Expected change in abundance or population structure at locations where the species
already occurs: Population structure will change to occasional or older age classes due to
infrequent recruitment.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: This species requires a low temperature (below 8ºC) to reproduce
successfully, which is unlikely to be present during the period that spawning normally occurs
and which may be triggered by the phytoplankton bloom (Meidel & Scheibling, 1998b).
Species that might be affected by decreased abundance of this species: It is not
expected that any species will be affected as the grazing activities of Strongylocentrotus are
likely to be no different in effect to those of Echinus esculentus which occurs in the same
habitats in Scotland.
Effects on biotopes: The only biotope in which Strongylocentrotus is specifically mentioned
as sometimes present is MCR.Bri.Oph.Oacu (Ophiopholis aculeata beds on slightly tide-swept
circalittoral rock or mixed substrata). It probaly also occurs in MCR.GzFa.FaAlC ( Faunal and
algal crusts, Echinus esculentus, sparse Alcyonium digitatum and grazing-tolerant fauna on
moderately exposed circalittoral rock). However, loss from these biotopes will be
compensated for by the continued grazing activities of Echinus esculentus,
Suggested monitoring: Recording scheme by volunteer divers guided to locations. Part of a
programme of searching for a small range of easily identified species.
References:
Meidel, S. K. and Scheibling, R. E. (1998a). Size and age structure of the sea urchin,
Strongylocentrotus droebachiensis, in different habitats. In Echinoderms San Francisco (eds:
Mooi, R. & Telford, M.), pp 737-742, AA Balkema, Rotterdam.
Meidel, S. K. and Scheibling, R. E. (1998b). Annual reproductive cycle of the green sea
urchin, Strongylocentrotus droebachiensis, in differing habitats in Nova Scotia, Canada.
Marine Biology, 131, 461-478.
Strathmann, M. F. (1987). Reproduction and development of marine invertebrates of the
northern Pacific coasts. University of Washington Press.
187
16.
Holothuria forskali
Image: Holothuria forskali. Lundy.
Picture width c.30 cm. Keith
Hiscock.
Common name: Cotton spinner
Current
A southern species recorded in a few
distribution: locations off west Scotland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Likely to increase in abundance and extent at current locations to become more
widely distributed in those locations and, following a 2ºC rise in temperature, may become
generally distributed on the west coast of Scotland.
Climate change type: Type F, southern gradual extenders.
Expected change in distribution: Likely to become more widespread in the areas where it
currently occurs following a 1ºC rise in seawater temperature and present in suitable habitats
all along the west coast of Scotland following a 2ºC rise in temperature.
Explanation: Reproduction is temperature dependant (Tuwo & Conand, 1992) and so larvae
will be produced more frequently and/or in larger numbers. The larvae are planktotropic and
so are likely to spread to distant locations. However, geographical barriers may slow
distribution.
188
Expected rate of change in distribution: Change will occur more-or-less in concert with
temperature rise.
Explanation: The larvae are planktotropic and so are likely to spread to distant locations
providing geographical barriers do not interfere.
Expected change in abundance or population structure at locations where the species
already occurs: Increase.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Holothuria forskali appears, in its present distribution, to favour open coast
areas in Scotland. It is likely that there will be some incursion to enclosed areas where
suitable substrata exist but not into sea lochs; Holothuria does not generally occur in extreme
shelter.
Species that might be displaced by increased abundance of this species: None.
Effects on biotopes: Holothria forskali is a characteristic species in ECR.Efa.CCParCar
(Coralline crusts, Parasmittina trispinosa, Caryophyllia smithii, Haliclona viscosa, polyclinids
and sparse Corynactis viridis on very exposed circalittoral rock) and MCR.ErSEun (Erect
sponges, Eunicella verrucosa and Pentapora foliacea on slightly tide-swept moderately
exposed circalittoral rock). The latter biotope might develop in Scotland following significant
seawater temperature rise.
Suggested monitoring: Recording scheme by volunteer divers guided to locations. Part of a
programme searching for a small range of easily identified species.
References:
Tuwo, A. & Conand, C. (1992). Reproductive biology of the holothurian Holothuria forskali
(Echinodermata). Journal of the Marine Biological Association of the United Kingdom, 72,
745-758.
189
17.
Cucumaria frondosa
Image: Cucumaria frondosa. Faroe
Islands. Image width c. 20 cm.
Bernard Picton.
Common name: Northern sea
cucumber
Current
A northern species widely recorded in
distribution: Shetland and also occurs in Orkney.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Cease to be present in Scottish waters following a 1ºC rise in seawater
temperature.
Climate change type: Type C, Northern retreater
Expected change in distribution: Cease to be present in Scottish inshore waters (1ºC).
Explanation: The current recorded distribution seems to be restricted to areas where summer
surface temperatures inshore do not rise above 13ºC. It is possible that lethal temperature for
adults is important as optimal embryonic development was found to occur at 12 ºC (Hamel &
Mercier, 1996): a temperature that occurs within the range of seawater temperatures that
occur during the year. The species is anyway very sparse in occurrence in Scottish locations
and it is questionable whether populations are viable.
Expected rate of change in distribution:
Retreat in distribution slow. Possibly with a ten to 20 year lag after temperature reaches
defined levels. (Adults are likely to survive and remain in the same areas but will eventually
190
die and not be replaced.)
Expected change in abundance or population structure at locations where the species
already occurs: Significant but gradual decline in abundance expected.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise:
Species that might be affected by decreased abundance of this species: None.
Effects on biotopes: None detectable.
Suggested monitoring:
Recording scheme by volunteer divers guided to locations. Part of a programme searching for
a small range of easily identified species.
References:
Hamel, J.-F., & Mercier, A. (1996). Early development, growth and spatial distribution of the
sea cucumber Cucumaria frondosa (Echinodermata: Holothuroidea). Canadian Journal of
Fisheries & Aquaculture Sciences, 53, 253-271.
191
18.
Lithothamnion glaciale
Image:
No image available
Common name: Maerl
Current
Widespread and often abundant in
distribution: the Arctic region and reaches its
southern limit of distribution in Britain
(Yorkshire, Lundy) and Ireland
(Galway, Down).
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Existing populations will persist for a considerable time (decades or centuries) but
decline slowly and be replaced by other maerl species with a more southerly distribution.
Climate change type: Type B, Northern stables
Expected change in distribution: Gradual decline over decades and eventual retreat
northwards.
Explanation: There is no information on temperature thresholds for the formation of
reproductive structures so that impacts of seawater warming on recruitment are uncertain.
Growth rate is optimum at 10-13°C, and growth rates decrease above that temperature (Adey,
1970). Temperatures within that range are likely to continue to occur but the constraint in
growth at higher temperatures agrees with the northern, cold-water distribution of L. glaciale,
192
the southern distributional limit of which in Britain and Ireland coincides with the 14.5°C
summer isotherm. A simplistic extrapolation from the present distributional range limit to
match a 1°C rise in summer sea temperatures would probably affect only the marginal
populations of L. glaciale in Ireland, southern England, the Isle of Man and Yorkshire.
Although the distributional range may remain unaffected in Scotland perhaps its abundance at
littoral and shallow sublittoral levels may change. A further increase by 1°C would imply a
continued reduction in southern extent but continued occurrence in northern and north-eastern
Scotland, Orkney and Shetland. Decline in abundance and loss may be more marked in
shallow waters than at depth.
Expected rate of change in distribution: It is uncertain as to how long existing populations
will remain viable, succumb to raised temperatures, or whether there will be a differential
decline according to depth.
Expected change in abundance or population structure at locations where the species
already occurs: Maerl beds in Britain and Ireland are principally formed of three species of
crustose coralline algae (Lithothamnion corallioides, Lithothamnion glaciale, and
Phymatolithon calcareum). P. calcareum has a widespread distribution in Britain and Ireland
(Norway to Spain and the Mediterranean) while L. corallioides is a southern species that
possibly reaches its northern distributional limit in Scotland and Northern Ireland. At present L.
glaciale replaces L. coralloides as a companion to P. calcareum in northern Britain. This may
be reversed with a 2°C rise in sea temperature thus changing the species composition of the
actively growing coralline components of the maerl beds.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Depth, grazing.
Species that might be displaced by increased abundance of this species: None.
Effects on biotopes: Probably many sublittoral rock biotopes with encrusting Corallinaceae
as characterising species will change constituent encrusting Corallinacea species (loss of
Lithothamnion glaciale) but associated species and the biotopes will remain the same.
IGS.Mrl.Lgla (Lithothamnion glaciale maerl beds in tide-swept variable salinity infralittoral
gravel) are similar in componant species to maerl beds dominated by Phymatolithon
calcareum and are likely, but not for many years, to change to those biotopes.
IGS.Mrl.Phy Phymatolithon calcareum (maerl beds in infralittoral clean gravel or coarse sand)
biotopes may have Lithothamnion glaciale as a minor component but would persist even if
Lithothamnion glaciale was lost.
Suggested monitoring: Measure cover of populations of encrusting Lithothamnion glaciale at
all shore levels (along transect lines) at selected sites around the Scottish coast.
Record abundance of live Lithothamnion glaciale in selected maerl beds especially Caol
Scotnish Narrows, Loch Sween.
References:
Adey W.H. (1970). The effects of light and temperature on growth rates in boreal-arctic
subarctic crustose corallines. Journal of Phycology, 6, 269-276.
Adey W.H. & Adey P.J. (1973). Studies on the biosystematics and ecology of epilithic
crustose Corallinaceae of the British Isles. British Phycological Journal, 8, 343-408.
Irvine L.M. & Chamberlain Y.M. (1994). Seaweeds of the British Isles Vol1. Rhodophyta Part
2B Corallinales, Hildenbrandiales. The Natural History Museum, London.
193
19.
Odonthalia dentata
Image: Odonthalia dentata in a
rockpool at Inchkeith. Image
width c. 20 cm. David
Irvine/NHM.
Common name:
Current
A circum-arctic species with a
distribution: southern limit of distribution at the
Isle of Man, Flamborough Head, and
western Ireland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Change in distribution and abundance will probably only occur in Scotland
following a 2°C rise in seawater temperature when the species may disappear from southern
Scotland.
Climate change type: Type B, Northern retreaters
Expected change in distribution: A simplistic extrapolation from the present southern
distribution limit of O. dentata that follows the 14.5°C summer isotherm suggests that with a
1°C rise in sea temperature the species would remain in areas where it is currently frequent
(all of the Scottish coast) but perhaps retreat north from the west coast of Ireland to Ulster,
from the Isle of Man to Galloway and from Yorkshire to Durham. A 2°C rise in sea
temperature and a shift north of the 14.5°C isotherm suggests a retreat from the west coast of
Scotland to the north of Scotland, and from Durham to Aberdeen. O. dentata will probably
194
remain in Orkney and Shetland.
Explanation: Increase in sea temperature will probably exceed the reproductive maximum
lethal limits (such limits have not been experimentally determined) and reduce reproductive
success at the Isle of Man and elsewhere at its southern limit of distribution. Kain (1982)
observed that its seasonality in reproduction can be related to geographical distribution. O.
dentata reproduces on the Isle of Man when sea temperature is below the annual mean of
10.7°C, typical of a species with a northern distribution. Kain also noted a possible change in
reproductive timing with latitude. In Scotland, Denmark and Newfoundland reproductive
seasonality is similar to the Isle of Man. In Shetland and north Norway tetraspores were
reported in August in contrast to February/March on the Isle of Man – thus a shift to summer
sporing at higher latitude.
It is also possible that populations may survive in refugia in deeper colder waters – although
Kain (1984) observed lower growth rates and plant sizes, and also fluctuation of plant
densities in deeper waters.
Expected rate of change in distribution: Retreat is likely to be moderately rapid. Individual
plants may survive to 4 or even 9 years but lack of recruitment will mean noticable decline at
its southern limits. Initially the rate of retreat in distribution is likely to be slow as suggested by
the map showing the 1°C rise in sea temperature. The 2°C rise will be more significant with
any relict populations south of the suggested limit not self sustaining.
Expected change in abundance or population structure at locations where the species
already occurs: There may be a significant decrease in abundance except in the north and
northeast of Scotland, Orkney and Shetland. Decrease may be expected in summer biomass
at the new southern limits of distribution (cf Kain, 1984).
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: None
Species that might be displaced by increased abundance of this species: None
Effects on biotopes: Odonthalia is mentioned as a characterising species only in biotope
EIR.KfaR.LhypFa (Laminaria hyperborea forest with a faunal cushion (sponges and
polyclinids) and foliose algae on very exposed infralittoral rock. It may be lost from the biotope
in much of Scotland.
Suggested monitoring: Recording scheme by volunteer divers guided to locations. Part of a
programme searching for a small range of easily identified species. If experienced biologists
undertake survey, count individuals per square metre, measure size of plants, note
reproductive phenology.
References:
Kain J.M. (1982). The reproductive phenology of nine species of Rhodophyta in the subtidal
region of the Isle of Man. British Phycological Journal, 17, 321-331.
Kain J.M. (1984). Seasonal growth of two subtidal species of Rhodophyta off the Isle of Man.
Journal of Experimental Marine Biology and Ecology, 82, 207-220.
Lüning K. (1990). Seaweeds their environment, biogeography and ecophysiology. Wiley &
Sons, New York.
Maggs C.A. & Hommersand M.H. (1993). Seaweeds of the British Isles Vol. 1 Rhodophyta
Part 3A Ceramiales. The Natural History Museum, London.
195
20.
Dictyopteris membranacea
Image:
No image available
Common name:
Current
A Mediterranean-Lusitanian species
distribution: that occurs in the east Atlantic
between the Canary Islands and
Mauritania in the south and western
Scotland in the north. Its northern limit
of distribution is the island of Tiree
where it grows at sublittoral levels
(21m).
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in winter
seawater
temperatures.
Key:
Likely future
distribution
Summary: Likely to spread northwards and increase in abundance where it currently occurs.
Spread is likely to be related to winter temperatures.
Climate change type: Type G, Southern rapid extenders.
Expected change in distribution: Range extension north to Duncansby Head, Orkney and
196
possibly Shetland following a 1ºC rise in temperature and all around the coast of Scotland
following a 2ºC rise.
Explanation: A simplistic extrapolation from the present distributional range limit coincident
with the 13.5ºC summer isotherm, to follow a 1ºC rise with the 13.5ºC isotherm displaced to
the north would suggest that Dictyopteris membranacea may spread around the entire coast of
Scotland to the Orkney Islands. A 2ºC rise might allow the species to spread to Shetland.
However, the distributional range limit follows the winter 7.5ºC isotherm which is probably
most critical to the occurrence of this southern (warm water) species in northern waters. A
simplistic extrapolation from this boundary to follow a northward displaced 7.5ºC isotherm as a
result of a 1ºC rise in sea temperature, would suggest a range extension of D. membrancea to
Duncansby Head (not as far as implied by a shift of the summer isotherm), Orkney and
possibly also Shetland. A further rise of 1ºC could hypothetically allow the species to spread
to the east coast of Scotland. This conclusion must remain speculative until data on the
environmental tolerance of the species is available.
Expected rate of change in distribution: Uncertain but, to speculate, a 2ºC rise in sea
temperature could allow for the full development of the of the Delesseriaceae-DictyotaDictyopteris assemblage in south west Scotland.
Expected change in abundance or population structure at locations where the species
already occurs: Likely to become more abundant especially in south-west Scotland.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Uncertain
Species that might be displaced by increased abundance of this species: Uncertain.
Effects on biotopes:
Biotope EIR.SG.FoR.Dic (Foliose red seaweeds with dense Dictyota dichotoma and/or
Dictyopteris membranacea on exposed lower infralittoral rock) may become more widespread
in Scotland, particularly a facies with Dictyopteris membranacea as a characterising species.
Suggested monitoring:
Recording scheme by volunteer divers guided to locations. Part of a programme searching for
a small range of easily identified species. Sites on Tiree should especially be targetted.
References:
Maggs C.A. (1986). Scottish marine macroalgae: a distributional checklist, biogeographical
analysis and literature abstract. A report to the Nature Conservancy Council. Queen’s
University, Belfast.
197
21.
Codium adhaerens
Image:
No image available
Common name:
Current
Occurs commonly in the south west
distribution: of England, sporadically around
Ireland, on the Isle of Man and at two
locations on the south-west coast of
Scotland (Loch Melfort in Argyll, Loch
nan Uamnh in west Inverness).
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in winter
seawater
temperatures.
Key:
Likely future
distribution
Summary: Occurrence is likley to increase within its present distributional range and range
extension will occur linked to changes in winter temperatures.
Climate change type:
Expected change in distribution: A simplistic extrapolation of the current distributional range
limit to coincide with a shift to the north of the 13.5ºC summer isotherm after a 1ºC rise in sea
temperature, would suggest a possible spread of C. adhaerens throughout Scotland to Orkney
198
and possibly also Shetland. A 2ºC rise in summer sea temperatures would seemingly make
no further difference. Repeating the exercise using the limiting winter 7ºC isotherm suggests
that following a 1ºC rise in winter sea temperature C. adhaerens may spread to the north of
Scotland at Duncansby Head, Orkney and Shetland. A further 1ºC rise in winter sea
temperature implies a spread to the east coast of Scotland (and north-east England). These
conclusions remain speculative pending studies on the environmental tolerance of C.
adhaerens throughout its life-cycle.
Expected rate of change in distribution: Uncertain, little is known of the biology of C.
adhaerens in relation to dispersal.
Expected change in abundance or population structure at locations where the species
already occurs: Mats of C. adhaerens may increase in size and spread vegetatively.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Uncertain.
Species that might be displaced by increased abundance of this species: May
outcompete other lower littoral species of moderately wave-exposed habitats.
Effects on biotopes: Not featured in any British and Irish biotopes. Tittley & Neto (2000)
proposed that the prostrate Codium adhaerens on shores in the Azores should characterise a
distinct biotope.
Suggested monitoring:
Populations in Scotland: measure vegetative growth; check for development of reproductive
structures.
References:
Burrows, E. M. (1991). Seaweeds of the British Isles Vol. 2 Chlorophyta. Natural History
Museum, London.
Knight M. & Parke M. (1931). Manx Algae. LMBC Memoirs, 30, 1-147.
Parke M. (1936). Algological records for the Manx region. Report of the Marine Biological
Station, Port Erin, Isle of Man for 1935: 29-32.
Powell H.T. (1966). The occurrence of Codium adhaerens (Cabr.) C. Ag. in Scotland, and a
note on Codium amphibium Moore ex Harv. In Some Contemporary Studies in Marine
Science (ed. H. Barnes), pp 591-595. Allen & Unwin, London.
Tittley, I. & Neto A.I. (2001). A provisional classification of algal-characterised rocky shore
biotopes in the Azores. Hydrobiologia (in press).
199
22.
Bifurcaria bifurcata
Image: Mass of Bifurcaria bifurcata in
a rockpool. Image width c. 80
cm. Cape Cornwall. Keith
Hiscock.
Common name:
Current
Eastern Atlantic Ocean between
distribution: Morocco in the south and Northern
Ireland in the north. Its present
northern limit of range distribution lies
on the same latitude as southern
Scotland and the nearest population
to Scotland lies approximately 120km
to the west.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Bifurcaria bifurcata is most likely restricted in distribution by winter temperatures
but also seems slow to colonise rockpools so might not extend to Scotland for many years
after seawater temperatures apparently become amenable.
Climate change type:Type F, gradual southern extenders
200
Expected change in distribution: Following a winter increase of 1ºC Bifurcaria could
potentially spread to the south west coast of Scotland to Skye and possibly the Outer
Hebrides. With a further 1ºC in winter sea temperature the distributional range of Bifurcaria
could spread to the north of Scotland, Orkney and Shetland (but probably not the east coast).
Explanation: A simplistic extrapolation of Bifurcaria distribution to match its current range limit
defined by the 14ºC summer isotherm would, with a 1ºC rise, extend its range distribution to
include the western seaboard of Scotland almost to Cape Wrath. An additional 1ºC rise in sea
temperature shifts the 14ºC isotherm further north and suggests that the species could spread
throughout Scotland (including the east coast) to Orkney and Shetland. However, Bifurcaria is
a warm water species the distribution of which coincides with and is probably limited by the 8º9ºC winter isotherm. De Valéra (1962) recorded fertile plants in February, and Rees (1933)
recorded them in April and July. In general receptacles are abundant in the darker, colder
months of the year. The expected change in distribution is therefore identified on the basis of
winter isotherms. These conclusions remain speculative until work on the environmental
responses and tolerances of the various life history stages of Bifurcaria bifurcata have been
undertaken.
Expected rate of change in distribution: Possibly slow; de Valéra (1962) noted that
Bifurcaria bifurcata may be a slow starter needing the protection of other species which it may
eventually outcompete. Drift fertile plants remain viable and may facilitate spread of Bifurcaria
to an appropriate habitat where zygotes can germinate. However, germlings are only rarely
noted in nature.
Expected change in abundance or population structure at locations where the species
already occurs: May become more abundant at range margins.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Winter sea temperature; competition with other species for space in pools
and open rock faces. Daylength may be important.
Species that might be displaced by increased abundance of this species: Uncertain.
Effects on biotopes: LR.Rkp.CorBif (Bifurcaria bifurcata in shallow eulittoral rock pools) may
become present in Scotland.
Suggested monitoring: Recording scheme by volunteers guided to locations. Part of a
programme searching for a small range of easily identified species.
References:
De Valéra (1962). Some aspects of the problem of the distribution of Bifurcaria bifurcata
(Velley) Ross on the shores of Ireland, north of the Shannon Estuary. Proceedings of the
Royal Irish Academy, 62, 77-99.
Lüning K. (1990). Seaweeds: their environment, biogeography and ecophysiology. Wiley &
Sons, New York.
201
23.
Fucus distichus distichus
Image: Fucus distichus distichus.
Cape St Francis,
Newfoundland. Image width c.
20 cm. Ian Tittley.
Common name:
Current
A northern species recorded as far
distribution: south as Islay and Ireland.
Prediction of future changes in distribution:
Likely distribution
assuming a 1°C
(left) or 2°C (right)
rise in summer
seawater
temperatures.
Key:
Likely future
distribution
Summary: Populations are likely to persist at the locations where they currently occur as
distribution is most likely determined by daylength rather than temperature.
Climate change type: (Closest to Type B, Northern stables)
Expected change in distribution: None.
Explanation: With the exception of the St Kilda population, Fucus distichus distichus in Britain
does not occur south of the summer 13°C isotherm. A simplistic extrapolation from the
present distributional range would suggest that following a 1°C and 2°C rise in summer sea
temperature, the 13°C isotherm would have moved north of the British Isles and distichus
would therefore become extinct in Britain. However, laboratory and autecological field studies
indicate that mature distichus plants can tolerate higher temperatures (see above). Embryos
also develop at 15°C (and higher). A critical factor is probably day length; short day lengths
stimulate the onset of receptacle formation and this will not change with global warming. Bird &
McLachlan (1976) showed that the formation of receptacles was independent of temperature
202
but maturation progressed with increasing temperature to at least 15°C. It is a possibility that
a 2°C rise in sea temperature may make no difference to the populations of distichus in
northern Scotland. Stormier sea conditions (predicted as a result of global warming) and
competition from other marine organisms may do so. Why distichus does not occur more
widely in Britain, as could be inferred from laboratory and autecological studies (and also
shown by subspecies anceps) remains unclear.
Expected rate of change in distribution: Uncertain, may be no change.
Expected change in abundance or population structure at locations where the species
already occurs: Uncertain, may be no change. If losses occur and viable population persist
elsewhere, recolonising is likely to be reasonably rapid. In Canada a pool was recolonised
only a year after denudation. However, establishment of a new population is a lengthy
process. Growth of sporelings is slow and no receptacles are formed in the first year.
Factors that may effect or restrict distribution changes in relation to seawater
temperature rise: Changes in daylength and frequency of storms are likely to affect
distribution.
Species that might be displaced by increased abundance of this species: Not applicable.
Effects on biotopes: Fucus distichus distichus is not mentioned as a characterising species
in any biotopes and it is most likely that change will not occur.
Suggested monitoring: Populations to be surveyed at selected sites following field methods
of Edelstein & McLachlan (1975).
References:
Bird, N.L. & McLachalan, J. (1976). Control of formation of receptacles in Fucus distichus L.
ssp. Distichus (Phaeophyceae: Fucales). Phycologia, 15, 79-84.
Edelstein, T. & McLachlan, J. (1975). Autecology of Fucus distichus ssp distichus
(Phaeophyceae: Fucales) in Nova Scotia, Canada. Marine Biology, 30, 305-324.
McLachlan, J. (1974). Effects of temperature and light on growth and development of
embryos of Fucus edentatus and Fucus distichus ssp distichus. Canadian Journal of Botany,
52, 943-951.
McLachlan, J., Chen L.C. & Edelstein T. (1971). The culture of four species of Fucus under
laboratory conditions. Canadian Journal of Botany, 49, 1463-1469.
Pearson, G.A. & Brawley, S.H. (1996). Reproductive ecology of Fucus distichus
(Phaeophyceae): an intertidal alga with successful fertilisation. Marine Ecology Progress
Series, 143, 211-223.
Powell, H.T. (1957). Studies in the genus Fucus L. I. Fucus distichus L. emend Powell.
Journal of the Marine Biological Association of the United Kingdom, 36, 407-432.
Rice, E.L. & Chapman, A.R.O. (1985). A numerical taxonomic study of Fucus distichus
(Phaeophyta). Journal of the Marine Biological Association of the United Kingdom, 65, 433459.
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